UNIVERSIDAD COMPLUTENSE DE MADRID · 2016-08-04 · El surfactante pulmonar es secretado por los...
Transcript of UNIVERSIDAD COMPLUTENSE DE MADRID · 2016-08-04 · El surfactante pulmonar es secretado por los...
UNIVERSIDAD COMPLUTENSE DE MADRID
FACULTAD DE CIENCIAS QUÍMICAS
Departamento Bioquímica y Biología Molecular I
TESIS DOCTORAL
Respuesta del pulmón frente al daño por ventilación mecánica Papel del surfactante pulmonar
MEMORIA PARA OPTAR AL GRADO DE DOCTOR
PRESENTADA POR
Virginia Egido Martín
Directora
Cristina Casals Carro
Madrid, 2014
©Virginia Egido Martín, 2013
UNIVERSIDAD COMPLUTENSE DE MADRID
FACULTAD DE QUÍMICAS
DEPARTAMENTO DE BIOQUÍMICA Y BIOLOGÍA MOLECULAR I
RESPUESTA DEL PULMÓN FRENTE AL DAÑO
POR VENTILACIÓN MECÁNICA: PAPEL DEL
SURFACTANTE PULMONAR
TESIS DOCTORAL DE
VIRGINIA EGIDO MARTÍN
DIRECTORA
DRA. CRISTINA CASALS CARRO
MADRID, 2013
COMPLUTENSE UNIVERSITY OF MADRID
CHEMISTRY SCHOOL
DEPARTMENT OF BIOCHEMISTRY AND MOLECULAR BIOLOGY I
LUNG RESPONSE AGAINST VENTILATOR-
INDUCED LUNG INJURY: ROLE OF
PULMONARY SURFACTANT
DOCTORAL THESIS OF
VIRGINIA EGIDO MARTÍN
DIRECTOR
DR. CRISTINA CASALS CARRO
MADRID, 2013
A mi padre
A mi madre
A mis princesas
The research for this thesis has been conducted in the Department of Biochemistry
and Molecular Biology I of Complutense University of Madrid, under the supervision
of Professor Cristina Casals.
This project has been performed in close collaboration with the Intensive Care Unit of
Getafe University Hospital supervised by Dr. Andrés Esteban.
The completion of this thesis was possible thanks to the funding of the Ministry of
Science and Innovation [SAF2006-04434 (FPI Grant: BES2008-009128), SAF2009-
07810, and SAF2012-32728] and the support of CIBER of Respiratory Diseases
(Institute of Health Carlos III-CB06/06/0002).
ABBREVIATIONS
ABCA3: ATP-binding cassette, sub-family A, member 3
ALI: Acute lung injury
ALT: Alanine aminotransferase
ARDS: Acute respiratory distress syndrome
ARDSnet: ARDS network
ASMase: Acid sphingomyelinase activity
AST: Aspartate aminotransferase
ATI: Alveolar type one cells
ATII: Alveolar type two cells
ATS: American respiratory society
BAL: Bronchoalveolar lavage free of cells
BM: Basement membranes
CBS: Captive bubble surfactometer
Ch: Cholesterol
CK: Creatinine kinase
CRP: C-reactive protein
CRS: Dynamic respiratory system compliance
DNPH: 2.4-Dinitrophenylhydrazine
DPPC: Dipalmitoyl phosphatidylcholine
DPPG: Dipalmitoyl phosphatidylglycerol
ECM: Extracellular matrix
EGF: Epithermal growth factor
ELISA: Enzyme-linked immunosorbent assay
ER: Endoplasmic reticulum
FBS: Fetal bovine serum
FSC: Forward scatter
FiO2: Fraction of inspired oxygen
HEPES: 4-(2-Hydroxyethyl)-1-piperazineethanesulfonic acid
ICAM-1 Intracellular adhesion molecule 1
IFN- Interferon gamma
IL-1-4-6-8-10-12-13 Interleukin-1-4-6-8-10-12-13
KC Keratinocyte-derived chemokine
LA Large aggregates of pulmonary surfactant
LB Lamellar bodies
LBP Lipopolysaccharide-binding protein
LDH Lactate dehydrogenase
LPO Lipid hydroperoxides
LPS Lipopolysaccharide
MAP Mean arterial pressure
MCP-1 Monocyte chemotactic protein-1
MIP-2 Macrophage inflammatory protein 2
MMP-2-9 Metalloproteinase-2-9
MSC Mesenchymal stem cells
MV Mechanical ventilation
MVB Multivesicular bodies
NFB Nuclear factor kappa B
PaO2 Partial pressure of arterial oxygen
PaCO2 Partial pressure of carbon dioxide
PAW Peak airway pressure
PAWP Pulmonary artery wedge pressure
PBS Phosphate buffered saline
PC Phosphatidyl choline
PE Phosphatidyl ethanolamine
PEEP Positive end-expiratory pressure
PG Phosphatidyl glycerol
PI Phosphatidyl inositol
Pi3K Phosphatidyl inositol-3-kinase
PIP Peak inspiratory pressure
PL Phospholipids
POPG 1-Palmitoyl-2-oleoyl-sn-glycero-3-phosphoglycerol
PS Pulmonary surfactant
PVDF Polyvinylidene difluoride
RDS Neonatal respiratory distress syndrome
RNS Reactive nitrogen species
ROS Reactive oxygen species
SA Small aggregates of pulmonary surfactant
SD Sprawley-Dawley
SDS Sodium dodecyl sulfate
SM Sphingomyelin
SMC Smooth muscle cells
SP-A-B-C-D Pulmonary surfactant-associated protein –A-B-C-D
SSC Side scatter
TCA Trichloroacetic acid
TGF-- Transforming growth factor-alpha-beta
Th1 Type 1 helper T cell
Th2 Type 2 helper T cell
TLR-2-4 Toll-like receptor -2-4
TM Tubular myelin
TNF- Tumor necrosis factor-alpha
VALI Ventilator-associated lung injury
VILI Ventilator-induced lung injury
VT Tidal volume
Surface tension
Pressure
1 Table of contents
Table of
contents
2 Table of contents
3 Table of contents
RESUMEN/SUMMARY……………………………………………….………….... 7
Resumen…………………………………………………………….………… 9
Summary………………………………………………………….……………17
INTRODUCTION……………………………………………………….……...….. 23
1. Respiratory system………………………………………......……………………. 24
2. Alveolar-capilarry unit………………………………….....………….……...….. 27
2.1. Pulmonary endothelium……………….....……………………….……….... 28
2.2. Pulmonary interstitium…………………………………………….….......... 29
2.3. Pulmonary epithelium……………………………………………….....….... 30
2.3.1. Alveolar epithelial type I cells...……………….…………………. 30
2.3.2. Alveolar epithelial type II cells………………………....………… 30
2.4. Pulmonary surfactant………………………………….……....……………. 31
2.4.1. Composition……………………………...….….………………….. 31
2.4.1.1. Lipid composition...................................................................... 32
2.4.1.2. Protein composition...................................................................
33
2.4.2. Metabolism........................................................................................ 43
2.4.2.1. Synthesis ans storage................................................................. 43
2.4.2.2. Secretion..................................................................................... 46
2.4.2.3. Recycling and turnover……..................................................... 49
2.4.3. Functions…………………………………………………………... 50
2.4.3.1. Surface tensión reduction in the air liquid interface............. 50
2.4.3.2. Alveolar-capillary fluid homeostasis………………....……... 52
2.4.3.3. Innate host defense……….………..……………….………… 54
2.5. Pulmonary immune system............................................................................ 55
3. Acute lung injury.................................................................................................... 58
3.1. Epidemiology................................................................................................... 59
3.1.1. Incidence........................................................................................... 59
3.1.2. Risk factors....................................................................................... 60
3.1.3. Outcomes........................................................................................... 61
3.2. Pathogenesis................................................................................................. ... 61
4 Table of contents
3.2.1. Endothelial and epitelial injury...................................................... 61
3.2.2. Inflammation.................................................................................... 62
3.3. Treatment........................................................................................................ 65
3.4. Animal models................................................................................................. 66
4. Ventilator-induced lung injury............................................................................. 68
4.1. Determinants of VILI..................................................................................... 69
4.1.1. Mechanical determinants................................................................ 69
4.1.2. Biotrauma......................................................................................... 70
4.2. Pathogenesis..................................................................................................... 72
4.2.1. Microscopic pathology..................................................................... 72
4.2.2. Alveolar edema................................................................................. 73
4.2.3. Inflammation.................................................................................... 73
4.2.4. Pulmonary surfactant alterations................................................... 76
4.2.5. Consequences following VILI…………………….…..…….….….76
OBJETIVES……………………………………………..…………………………… 79
MATERIALS AND METHODS…………………………………………...……… 83
1. Animals and experimental models……………………………………....……... 85
2. Registration of hemodynamic and ventilator parameters……..…..........……. 86
3. Biological sampling................................................................................................ 86
4. Arterial blood gases analysis................................................................................. 89
5. Alveolar fluid cells analysis……………………………...…....………….…....... 89
6. Histological analysis............................................................................................... 90
7. Isolation of large and small aggregates of pulmonary surfactant..................... 90
8. Total amount of phospholipids quantification…………………….…….…….. 91
9. Lipid peroxidation assessment.............................................................................. 91
10. Cholesterol quantification.................................................................................... 92
11. Total protein determination................................................................................. 92
12. Oxidized protein quantification............................................................................ 93
13. Damage markers quantification in BAL and plasma......................................... 93
14. Acid sphingomyelinase activity determination………………………….…….. 94
15. Determination of PS-associated proteins SP-A, SP-B and SP-C levels by
Electrophoresis and Western Blot analysis …………………………….……... 96
5 Table of contents
16. Gene expression analysis by rela time-PCR………………….………….…….. 98
17. Biophysical function of pulmonary surfactant…………………..………....... 100
CHAPTER 1: Characterization of alveolar injury due to high-stretch ventilation
1. Abstract………………………………………………………………………… 109
2. Introduction……………………………………………………...….…………. 109
3. Experimental design............................................................................................ 111
4. Results................................................................................................................... 112
4.1. Physiology...................................................................................................... 112
4.2. Alveolar injury.............................................................................................. 113
4.2.1. Cellular and histological analysis................................................. 114
4.2.2. Total protein and carbonylated protein in BAL………………. 115
4.2.3. Damage markers............................................................................ 116
4.3. Surfactant analysis........................................................................................ 117
4.3.1. Composition analysis..................................................................... 117
4.3.2. Pulmonary surfactant functionality............................................. 121
4.3.3. Presence of pulmonary surfactant inhibitors.............................. 122
5. Discussion……………………………………………………………….....……. 123
CHAPTER 2: Factors involved in the resistant to ventilator-induced lung injury
1. Abstract…………………………………………………………….…………… 129
2. Introduction…………………………………………………….....……………. 130
3. Experimental design............................................................................................. 131
4. Results.................................................................................................................... 133
4.1. Physiology....................................................................................................... 133
4.2. Alveolar injury............................................................................................... 135
4.2.1. Alterations in the alveolar space................................................... 135
4.2.2. Alveolar fluid cells……………………………….………………. 136
4.2.3. Damage markers............................................................................ 138
4.3. Surfactant analysis........................................................................................ 140
4.3.1. Pulmonary surfactant composition analysis............................... 140
4.3.2. Pulmonary surfactant functionality............................................. 143
4.3.2.1. Interfacial adsorption............................................................. 143
6 Table of contents
4.3.2.2. Captive bubble surfactometry............................................... 144
4.3.3. Presence of pulmonary surfactant inhibitors.............................. 147
5. Discussion………………………………………………………………….....…. 149
CHAPTER 3: Effect of prolonged low-stretch ventilation after injurious
high-stretch ventilation in resistant rats
1. Abstract……………………………………………………………….....…..…… 155
2. Introduction……………………………………………………….....……..……. 155
3. Experimental design.............................................................................................. 157
4. Results.................................................................................................................... 159
4.1. Alterations under long exposure to MV...................................................... 159
4.1.1. Physiology........................................................................................ 159
4.1.2. Alveolar injury............................................................................... 160
4.1.2.1. Intra-alveolar edema and histological injury score............ 160
4.1.2.2. Alveolar fluid cells………………………….…………...…. 160
4.1.2.3. Damage markers.................................................................... 162
4.1.3. Pulmonary surfactant analysis.................................................... 164
4.2. Comparison between short and long exposure to MV under the same
ventilator strategy………………………………….................................... 166
5. Discussion………………………………………………………………........…. 168
GENERAL DISCUSSION……………….…………………………………..…… 175
CONCLUSIONS………………………………………………………………...…. 181
REFERENCES………………………………………………………………...…... 185
ACKNOWLEDGEMENTS….………………………………….…………...…..... 215
7 Resumen/Summary
Resumen
Summary
8 Resumen/Summary
9 Resumen/Summary
INTRODUCCIÓN
Aún no se tiene un pleno conocimiento de la patogénesis del síndrome de distrés
respiratorio agudo (ARDS) y su forma menos severa, el daño pulmonar agudo (ALI)
(2). Sin embargo, actualmente se piensa que estos síndromes comienzan con una
respuesta inflamatoria que puede ser inducida por daños extra-pulmonares (sepsis,
trauma severo, pancreatitis aguda, etc.) o por alteraciones directas en el pulmón
(neumonía, contusión pulmonar, aspiración de ácidos gástricos, etc.) (3). Dicha
respuesta inflamatoria puede conllevar alteraciones en la permeabilidad de la barrera
alveolo-capilar, provocando edema intra-alveolar (3, 4). Ante este escenario, la
alteración del surfactante pulmonar complica aún más la situación (5).
El surfactante pulmonar es un complejo macromolecular esencial para mantener
el alveolo abierto y por consiguiente, permitir un adecuado intercambio gaseoso. Sin
surfactante, el alveolo colapsaría al no disminuir la tensión superficial de la interfase
aire-líquido durante la espiración (1, 6). Por tanto, una de las principales funciones del
surfactante pulmonar es establecer una monocapa en la interfase aire-líquido que
excluye las moléculas de agua de la interfase y por tanto disminuye la tensión
superficial a 1 mN/m en la espiración (1). Para llevar a cabo su función
correctamente, el surfactante pulmonar está formado por lípidos (principalmente
fosfolípidos) y apolipoproteínas específicas del surfactante, denominadas SP-A, SP-B
y SP-C.
El surfactante pulmonar es secretado por los neumocitos tipo II al fluido alveolar
en forma de agregados grandes (LA), que generan rápidamente una monocapa estable
en la interfase aire-líquido (1). Este proceso se denomina adsorción interfacial del
surfactante pulmonar. Después de la adsorción, la monocapa de surfactante está
sometida periódicamente a procesos de compresión durante la exhalación y de
expansión durante la inhalación. Los procesos de compresión producen cambios en la
tensión superficial (γ) de ~23 mN/m a ~1 mN/m para prevenir el colapso alveolar
mientras que la inspiración produce la expansión de la monocapa, produciéndose un
incremento de γ hasta 20–25 mN/m para mantener la estabilidad alveolar. Como
consecuencia de estos ciclos reiterados de compresión/expansión se van generando
vesículas no funcionales del surfactante pulmonar, denominadas agregados pequeños
(SA). Estas vesículas son capturadas continuamente por los neumocitos tipo II o los
macrófagos alveolares.
10 Resumen/Summary
La alteración o déficit del surfactante pulmonar conlleva edema intra-alveolar,
alteración en la compliance pulmonar, desajuste de la ventilación-perfusión e
hipoxemia (1, 5, 6).
La presencia de una acusada hipoxemia precisa de soporte ventilatorio, cuya
utilización ha requerido estudiar los posibles efectos adversos de la ventilación
mecánica per se, conocido como daño pulmonar agudo inducido por ventilación
mecánica (VILI) (7). Actualmente se considera que VILI se genera como
consecuencia de volutrauma (distensión pulmonar cuando se somete a presión
alveolar alta) y/o atelectrauma (causado por la apertura y el cierre cíclicas del espacio
aéreo) (7). Estas alteraciones pueden estimular la respuesta inflamatoria (denominado
biotrauma), resultando en daño pulmonar progresivo e inflamación sistémica (7).
Actualmente, el soporte ventilatorio para pacientes con ALI o ARDS consiste en
ventilar con bajo volumen corriente (para disminuir el volutrauma) y aplicar una
presión positiva al final de la expiración (PEEP) y/o un ratio de FiO2/PEEP adecuados
(para reducir el atelectrauma) (8). El PEEP aumenta la presión del espacio aéreo al
final de la espiración. Sin embargo, debido a que las presiones de apertura del espacio
aéreo pueden variar notablemente entre pacientes e incluso dependiendo del estado de
un mismo paciente, la aplicación de PEEP para revertir o limitar atelectasis dorsal-
caudal, casi siempre sucederá a costa de un exceso de distensión de las regiones
pulmonares ventrales u otras áreas que tienen presiones inferiores de apertura (9).
Dada la importancia de un correcto manejo de los parámetros ventilatorios para
mantener a los pacientes con ARDS y ALI (7, 8), se ha comenzado a estudiar el
efecto de la ventilación mecánica en pulmones sanos. Para ello, la utilización de
modelos animales expuestos a estrategias ventilatorias convencionales o dañinas es
indispensable para conocer mejor los mecanismos que inducen VILI.
En esta tesis, ratas sanas han sido expuestas a las siguientes estrategias ventilatorias
(10):
Ventilación mecánica perjudicial (HV) durante 2.5 h caracterizada por alto
volumen corriente (VT = 25 ml/kg) y ausencia de PEEP ya que nuestro objetivo
era provocar alteraciones alveolares causadas por volutrauma, atelectrauma y/o
biotrauma.
Ventilación mecánica convencional (LV) durante 2.5 h caracterizada por volumen
corriente moderado (VT = 9 ml/kg) y aplicación de PEEP (PEEP = 5 cm H2O), con
11 Resumen/Summary
el objetivo de simular la estrategia ventilatoria utilizada habitualmente en la
unidad de cuidados intensivos.
Ventilación mecánica convencional prolongada (VT = 9 ml/kg, y PEEP = 5 cm
H2O).
Ventilación mecánica convencional prolongada (VT = 9 ml/kg, y PEEP = 5 cm
H2O) después de 2.5 h de exposición a una estrategia ventilatoria dañina (VT = 25
ml/kg, y PEEP = 0). Este modelo simula situaciones clínicas en las que los
pacientes con alteraciones pulmonares son ventilados con estrategias ventilatorias
convencionales.
OBJECTIVOS
El objetivo principal de esta tesis fue estudiar los cambios morfológicos y
funcionales en pulmones ventilados con estrategias ventilatorias dañinas o
convencionales, así como identificar la relación entre la ventilación mecánica
agresiva, la inflamación, el edema y la disfunción del surfactante para poder entender
los mecanismos implicados en el daño pulmonar agudo inducido por ventilación
mecánica (VILI).
En este estudio contestaremos dos preguntas que actualmente están siendo
debatidas (9): si los cambios en la composición y funcionalidad del surfactante
preceden al comienzo de VILI y si VILI ocurre sólo en aquellos animales que tienen
inactivado el surfactante pulmonar.
Esta tesis se compone de tres capítulos los cuales evalúan:
El impacto de estrategias ventilatorias dañinas en el espacio alveolar y
concretamente sus efectos sobre la composición, estructura y funcionalidad del
surfactante pulmonar. Además se determinaron las causas de la inactivación del
surfactante tras la ventilación mecánica lesiva. (Chapter 1).
Los factores implicados en la resistencia al daño inducido por ventilación
mecánica debido a que dichos factores pueden contribuir a desarrollar terapias
profilácticas o intervenciones previas a la ventilación. (Chapter 2).
Las consecuencias de una ventilación mecánica convencional prolongada, con
o sin previa exposición a estrategias ventilatorias perjudiciales. Este estudio
permitiría determinar si la inflamación en el pulmón esta relacionada con la
12 Resumen/Summary
duración a la exposición de estrategias ventilatorias convencionales así como
dilucidar si dicha estrategia ventilatoria convencional tiene efectos beneficiosos
o perjudiciales en aquellos animales previamente expuestos a ventilación
mecánica lesiva. (Chapter 3).
RESULTADOS Y CONCLUSIONES
Capítulo 1
El objetivo de este capítulo fue caracterizar los cambios producidos en el
espacio alveolar debido a estrategias ventilatorias dañinas. La mayoría de los animales
expuestos a ventilación mecánica lesiva desarrollaron daño agudo (VILI)
caracterizado por: 1) presión parcial de oxígeno arterial/porcentaje de oxígeno
inspirado (PaO2/FiO2) < 300 mmHg; 2) evidencias de alteración tisular; 3) aumento
de marcadores inflamatorios tales como TNF-α y la actividad de la esfingomielinasa
ácida en BAL; 4) contaminación de proteínas plasmáticas en los alvéolos y aumento
de los niveles de la proteína carbonilada en BAL, e 5) inactivación del surfactante
pulmonar.
Aunque la ventilación con alto volumen corriente estimuló la secreción de
surfactante por parte de los neumocitos tipo II, éste fue rápidamente inactivado. La
inactivación del surfactante pulmonar puede deberse a la oxidación tanto de sus
componentes lipídicos como proteicos debido al estrés oxidativo, a la degradación de
los mismos por parte de fosfolipasas y proteasas y a la presencia de inhibidores de las
membranas del surfactante que provengan del torrente sanguíneo o bien sean
secretados por las células alveolares. En concreto, hemos observado una disminución
significativa en los niveles de las proteínas específicas del surfactante SP-A, SP-B y
SP-C, así como una disminución en sus niveles de expresión en el tejido pulmonar.
Además, hemos encontrado un aumento significativo de lípidos peroxidados en las
membranas del surfactante junto con un aumento significativo de la proteína C
reactiva (CRP), un inhibidor del surfactante que se inserta en sus membranas
alterando sus propiedades biofísicas (1).
13 Resumen/Summary
Conclusiones del C.1: Este estudio indica que estrategias ventilatorias lesivas
producen daño directo en el pulmón, promoviendo la inflamación, el estrés oxidativo
y la liberación de diversos factores, que todos juntos están implicados en la
inactivación del surfactante. Dicha inactivación conlleva atelectasis manifestada por
alteraciones en el intercambio gaseoso y disminución de la complianza dinámica.
Capítulo 2
Durante la realización del anterior estudio, observamos que un pequeño
número de animales expuestos a estrategias ventilatorias lesivas no mostraban
evidencias de disfunción pulmonar. Por consiguiente, el objetivo de este capítulo fue
identificar los factores involucrados en la resistencia al daño pulmonar agudo
inducido por ventilación mecánica. Para este propósito, el grupo ventilado con alto
volumen corriente y ausencia de PEEP fue dividido en dos grupos según sus valores
de presión arterial media (MAP) que se registraba continuamente: 1) animales
susceptibles a la ventilación mecánica lesiva (sHV), caracterizados por valores de
MAP inferiores a 50 mmHg y una acusada disminución de PaO2 tras 60 minutos de
ventilación: y 2) animales resistentes a la ventilación mecánica lesiva (rHV) los cuales
no tenían cambios sustanciales en MAP y PaO2 tras 60 minutos de ventilación.
El grupo sHV se caracterizó por: 1) PaO2/FiO2<200 mmHg; 2) alteraciones
histológicas incluyendo presencia de membranas hialinas; 3) Una disminución
acusada de macrófagos alveolares; 4) Edema intraalveolar; 5) Aumento de
marcadores inflamatorios en BAL (TNF-α, MIP-2, MCP-1, y actividad
esfingomielinasa ácida) y en plasma (MIP-2), y 6) Marcadas alteraciones en la
composición y funcionalidad del surfactante pulmonar tal y como se describen en el
Capítulo 1.
Por el contrario, el grupo rHV presentó una respuesta inflamatoria atenuada en
el pulmón, representada por un aumento de los niveles de IL-6 en BAL acompañada
de una disminución de TNF-α, MCP-1 y MIP-2, junto con ausencia de actividad
esfingomielinasa ácida. La ventilación mecánica estimuló la secreción de surfactante,
aislándose surfactante sin alteraciones en su composición ni presencia de
peroxidación lipídica. A diferencia del grupo sHV, el surfactante pulmonar de los
animales aislados del grupo rHV era capaz de: i) adsorberse y establecer una
monocapa estable en la interfase aire-líquido, ii) disminuir la tensión superficiales 1
14 Resumen/Summary
mN/m durante la compresión, y iii) re-extenderse durante la expansión. Aunque los
animales resistentes a las estrategias ventilatorias lesivas mostraron algunas
evidencias de daño tisular, disminución de células alveolares y liberación de
citoquinas proinflamatorias en BAL, estos animales no presentaron edema intra-
alveolar y una relación PaO2/FiO2 normal (450 mm Hg) tras 2.5 h de ventilación.
Conclusiones del C.2: Estos resultados indican que VILI se genera solo en aquellos
animales donde el surfactante pulmonar se encuentra inactivado y que hay una clara
relación entre una pronunciada respuesta pro-inflamatoria y la inactivación del
surfactante pulmonar. Además, estos resultados muestran que una respuesta
inflamatoria atenuada junto con un aumento de la secreción endógena de surfactante
activo protegen del desarrollo de edema intra-alveolar e hipoxia, sucesos típicos de
animales ventilados con estrategias ventilatorias lesivas.
Capítulo 3
El objetivo de este capítulo fue dilucidar el efecto de estrategias ventilatorias
convencionales prolongadas en animales previamente expuestos o no a estrategias
ventilatorias lesivas.
Se determinó que los individuos expuestos por un periodo de tiempo
prolongado a una ventilación mecánica convencional mostraban un aumento de
infiltración neutrofílica y de liberación de citoquinas proinflamatorias en el espacio
alveolar (IL-6 yMIP-2 pero no TNF-α) y en plasma (IL-6). Sin embargo, la respuesta
inflamatoria no fue lo suficientemente dañina como para producir daños histológicos,
alteraciones en el surfactante y disfunción pulmonar.
Por otro lado, se observó que la ventilación convencional prolongada tras
ventilar los animales con una estrategía ventilatoria lesiva tiene efectos nocivos en
aquellos animales que sobreviven a dicha estrategia ventilatoria r(HV+LV). Los
animales mostraron edema intra-alveolar, infiltración de neutrófilos, aumento de MIP-
2 en BAL y en plasma así como ligeras alteraciones en el intercambio gaseoso
mientras que el surfactante pulmonar no mostraba alteraciones. Estos datos indican
que las alteraciones en el espacio alveolar pueden sucederse sin alteraciones en el
surfactante pulmonar. Además, estos datos apoyan nuestra conclusión de que VILI se
presenta sólo en aquellos animales cuyo surfactante se encuentra inactivado, puesto
15 Resumen/Summary
que estos animales no desarrollan VILI. Es más, un pequeño número de animales no
sobrevivió a todo el proceso ventilatorio s(HV+LV) y presentó una respuesta
inflamatoria exacerbada, edema intra-alveolar, evidencias de alteraciones histológicas,
alteración en la composición y funcionalidad del surfactante y por consiguiente una
disminución significativa de la oxigenación arterial (PaO2/FiO2< 200 mmHg).
Conclusiones del C.3: Estos resultados indican que: 1) la inflamación en el pulmón
está directamente relacionada con la duración de la estrategia ventilatoria
convencional; 2) Que una adecuado funcionamiento del surfactante pulmonar es
esencial para la supervivencia de aquellas ratas expuestas a estrategias ventilatorias
lesivas y/o ventilación mecánica prolongada bajo estrategias no dañinas; y 3) Los
cambios en la composición y funcionalidad del surfactante pulmonar no preceden al
inicio del daño pulmonar agudo inducido por ventilación mecánica (VILI).
16 Resumen/Summary
17 Resumen/Summary
INTRODUCTION
The pathogenesis of acute respiratory distress syndrome (ARDS) and the less
severe condition known as acute lung injury (ALI) (2) is still not fully understood.
However, it is currently thought to begin with an inflammatory response induced by
extrapulmonary injury (sepsis, severe trauma, acute pancreatitis, etc.) or direct
pulmonary injury (pneumonia, aspiration of gastric contents, pulmonary contusion,
etc.) (3). The inflammatory response increases alveolar epithelial and pulmonary
vascular endothelial permeability, causing alveolar filling (3, 4). The alteration of the
pulmonary surfactant system complicates the clinical picture (5).
Surfactant is necessary to keep the alveolus open, thereby allowing gas exchange.
Without surfactant the alveoli collapse since the surface tension at the air–water
interface exerts a collapsing pressure (1, 6). Thus, one of the main lung surfactant
functions is to form a stable lipid monolayer at the air–liquid interface that excludes
water molecules from the interface and effectively lowers surface tension to 1mN/m
on expiration (1). To fulfill this function, the surfactant extracellular membranes are
composed of lipids (mainly phospholipids) and three surfactant apolipoproteins (SP-
A, SP-B, and SP-C). After surfactant secretion by epithelial type II cells, the secreted,
tightly packed surfactant membranes (known as large surfactant aggregates [LA])
rapidly transfer surface-active material to the air-liquid interface, forming the
surfactant monolayer (1). This process is known as interfacial adsorption of
surfactant. After adsorption, the surfactant film is periodically compressed during
exhalation and expanded during inhalation. Compression involves changes in surface
tension (γ) from~23 mN/m to ~1 mN/m to prevent alveolar collapse, whereas film
expansion increases γ to a maximum of 20–25 mN/m to maintain alveolar stability.
With repetitive surface compression and expansion cycles, small surfactant vesicles
with poor surface activity (known as small surfactant aggregates [SA]) are generated.
They are taken up continuously by alveolar macrophages and epithelial cells. Deficit
or alteration of lung surfactant leads to intraalveolar edema, impaired lung
compliance, ventilation-perfusion mismatch (including shunt flow due to altered gas
flow distribution), and hypoxemia (1, 5, 6).
Critical hypoxemia results in the need for mechanical ventilation, thereby
providing the context in which ventilator-induced lung injury (VILI) can develop (7).
It is thought that VILI is generated as a result of volutrauma (intensified tissue
18 Resumen/Summary
tensions at the junctions of closed and open alveolar units when subjected to high
alveolar pressure) and/or atelectrauma (caused by the cyclical airspace opening and
closing) (7). These stresses might further stimulate the inflammatory response (termed
biotrauma) resulting in progressive lung injury and systemic inflammation (7).
The current respiratory support in ALI or ARDS consists of low tidal volume (to
reduce volutrauma) and appropriate positive end-expiratory pressure (PEEP) and/or
FiO2/PEEP ratio (to reduce atectrauma) (8).
The application of PEEP is thought to be useful in counteracting increased
surface tension (thereby reversing the resulting atelectasis). PEEP increases end-
expiratory airspace pressure, but since airspace opening pressures can vary markedly
between and within patients, applying PEEP to reverse or limit dorsal-caudal
atelectasis will almost always come at the expense of over-distending ventral lung
regions and other areas having lower opening pressures (9).
Given the importance of ventilatory management for acute respiratory syndrome
(ARDS or ALI) (7, 8), investigators have started to explore the effects of ventilation
in healthy lungs. Animal models exposed to conventional and injurious ventilator
strategies are being used to understand the mechanisms of lung injury induced by
mechanical ventilation.
In this thesis, healthy rats have been exposed to the following ventilator strategies
(10):
Injurious high-stretch ventilation (HV) during 2.5 h, with high tidal volumes (VT
= 25 ml/kg) and without PEEP application since our aim was to provoke alveolar
alterations caused by volutrauma, atelectrauma, and/or biotrauma.
Conventional low-stretch ventilation (LV) during 2.5 h, with moderated tidal
volume (VT = 9 ml/kg) and application of positive end-expiratory pressure (PEEP
= 5 cm H2O), to emulate a ventilator strategy widely used in critical care units.
Prolonged conventional low-stretch ventilation (VT = 9 ml/kg, and PEEP = 5 cm
H2O).
Prolonged low-stretch ventilation (VT = 9 ml/kg, and PEEP = 5 cm H2O) after 2.5
h exposition to high-stretch ventilation (VT = 25 ml/kg, and PEEP = 0). This
condition simulates clinical situations in which patients with pulmonary
alterations are subjected to conventional mechanical ventilation.
19 Resumen/Summary
OBJECTIVE
The main objective of this thesis was to study morphological and functional
changes in the lungs after exposition to injurious or conventional mechanical
ventilation and to identify the relationship among high-stretch ventilation,
inflammation, edema, and surfactant dysfunction in order to understand the
mechanisms involved in ventilator-induced lung injury (VILI). Two important
questions, currently under debate (9), will be answered in this study: whether changes
in surfactant composition and in surface tension precede the onset of VILI, and
whether VILI occurs only in animal models when lung surfactant is inactivated.
The thesis is composed of three chapters, which evaluate:
The impact of high-stretch ventilation in the alveolar space and in particular its
effects on the composition, structure, and functional activity of lung surfactant.
The causes of surfactant inactivation after high-stretch ventilation were
assessed (Chapter 1).
Factors involved in resistance to ventilator-induced lung injury, since
identification of such factors may help to develop prophylactic therapies or
early interventions prior to exposition to mechanical ventilation (Chapter 2).
Consequences of prolonged conventional low-stretch ventilation, with or
without previous exposition to injurious high-stretch ventilation. This would
allow determination of whether inflammation in the lung was directly related to
the duration of conventional low-stretch ventilation and whether prolonged
conventional low-stretch ventilation has beneficial or damaging effects in
surviving rats exposed to injurious high-stretch ventilation (Chapter 3).
20 Resumen/Summary
RESULTS & CONCLUSIONS
Chapter 1
The aim of this chapter was to characterize changes produced in the alveolar
compartment due to injurious high-stretch mechanical ventilation. Most of the
animals exposed to injurious high-stretch ventilation developed lung injury (VILI),
which was characterized by 1) arterial oxygen tension/inspiratory oxygen fraction
(PaO2/FiO2) < 300 mmHg; 2) histological evidence of tissue injury; 3) increase of
inflammatory markers such as TNF- and acidic sphingomyelinase activity in BAL;
4) leakage of plasma proteins into the alveoli and increased levels of protein
carbonyls in BAL, and 5) loss of surfactant biophysical function.
Even though high-stretch ventilation stimulated surfactant secretion by type II
cells, surfactant is rapidly inactivated. Surfactant inactivation can rise from protein
and lipid oxidation as a consequence of oxidative stress, degradation of surfactant
lipids and proteins by phospholipases and proteases, and incorporation of inhibitors in
surfactant membranes leaked from capillaries or secreted by alveolar cells.
Specifically, we found a marked decrease in levels of surfactant apolipoproteins (SP-
A, SP-B, and SP-C) and reduced expression of these proteins by lung tissue, increased
levels of lipid peroxides in surfactant membranes, and increased levels of surfactant
inhibitors such as C reactive protein (CRP) that insert into surfactant membranes and
critically affect surfactant physical properties (1).
Ch.1 conclusions: This study indicates that injurious high-stretch ventilation
produces direct damage tothe lung, promoting inflammation, oxidative stress, and
release of factors that together inactivate lung surfactant. Surfactant impairment leads
to atelectasis as manifested by impaired gas exchange and decrease in dynamic
compliance.
21 Resumen/Summary
Chapter 2
During the previous study we realized that a number of animals subjected to
high-stretch ventilation did not show evidence of physiological lung dysfunction.
Hence, the aim of this chapter was to identify factors involved in the resistance to
ventilator-induced lung injury. To this end, the high-stretch ventilated group (HV)
was subdivided in two groups according to the mean arterial pressure (MAP) value,
which was continuously monitored: 1) animals susceptible to high-stretch
ventilation (sHV), showing MAP values lower than 50 mmHg and a substantial PaO2
reduction at 60 min of ventilation; and 2) animals resistant to high-stretch
ventilation (rHV), with insignificant MAP and PaO2 changes at 60 min. Lung tissue,
plasma, bronchoalveolar fluid (BAL), and lung surfactant were analyzed.
The sHV group was characterized by: 1) PaO2/FiO2<200 mmHg; 2) histological
evidence of tissue injury with hyaline membrane formation; 3) prominent decrease of
alveolar macrophages; 4) intraalveolar edema; 5) increase of inflammatory markers in
BAL (TNF-α, MIP-2, MCP-1, and acidic sphingomyelinase activity) and in plasma
(MIP-2); and 6) pronounced changes in the composition and function of lung
surfactant as reported in Chapter 1. In contrast, the rHV group was distinguished by
an attenuated lung inflammatory response, evidenced by increased levels of IL-6 in
BAL but reduced levels of TNF-α, MCP-1, and MIP-2 and absence of acidic
sphingomyelinase activity. High-stretch ventilation stimulated surfactant secretion,
and high amounts of fully active surfactant with normal protein and lipid composition
and absence of lipid peroxides were isolated from the lungs. Contrary to surfactant
isolated from lungs of the sHV group, surfactant from the rHV group was able to: i)
adsorb onto an air/water interface, ii) lower surface tension to values near 1mN/m
upon compression, and iii) re-spread during expansion. Even though animals resistant
to high-stretch ventilation showed evidence of some tissue injury, decrease in alveolar
macrophages, and release of proinflammatory cytokines in the alveolar fluid, these
animals did not exhibit plasma protein leakage into the alveolar space and showed
normal PaO2/FiO2 (450 mm Hg) after 2.5 h of ventilation.
Ch.2 conclusions: These results clearly indicated that VILI occurred only in animal
models when surfactant was inactivated and that there is a direct link between
pronounced proinflammatory response and surfactant inactivation. In addition, these
22 Resumen/Summary
results show that an attenuated inflammatory response together with increasing
endogenous, fully active, surfactant pools protect against the hypoxia and protein
leakage that usually occur when ventilating animals with large VT and no PEEP.
Chapter 3
The aim of this chapter was to elucidate the effect of prolonged conventional
low-stretch ventilation, with or without previous exposition to injurious high-stretch
ventilation. We found that animals subjected to prolonged conventional mechanical
ventilation showed neutrophils infiltration and increase of proinflammatory cytokines
in the alveolar space (IL-6 and MIP-2 but not TNF-α) and plasma (IL-6). However,
the inflammatory response was not damaging enough to show histological evidence of
tissue injury, pulmonary surfactant alteration, and evidence of physiological lung
dysfunction.
On the other hand, we found that prolonged conventional low-stretch ventilation
has damaging effects in surviving rats previously exposed to injurious high-stretch
ventilation (rHV+LV). Animals showed intra-alveolar edema together with
neutrophils infiltration, increase of MIP-2 in BAL and plasma, and slight alterations
in gas exchange, whereas pulmonary surfactant showed no evidence of impairment.
These studies indicate that alveolar damage can occur without parallel surfactant
damage. These animals were resistant to VILI and confirm our previous conclusion
that VILI occurred only in animal models when surfactant was inactivated.
Moreover, few animals did not survive the whole mechanical ventilation process
s(HV+LV) and exhibited exacerbated inflammatory response, edema, histological
evidence of tissue injury, alterations in the composition and function of pulmonary
surfactant, and consequently, significant decrease of arterial oxygenation (PaO2/FiO2<
200 mmHg).
Ch.3 conclusions: These results indicated that: 1) inflammation in the lung was
directly related to the duration of conventional low-stretch ventilation; 2) proper
functioning of pulmonary surfactant is essential for survival of rats exposed to
injurious and/or prolonged non-injurious mechanical ventilation, and 3) changes in
surfactant composition and function do not precede the onset of acute lung injury
induced by mechanical ventilation.
23 Introduction
Introduction
24 Introduction
25 Introduction
1. Respiratory system
Respiration defines the process by which gas exchange occurs between and
organism and its surrounding environment.
Specifically, the respiratory system supplies the body with adequate oxygen for
aerobic metabolism and removes its major waste product, carbon dioxide. To
accomplish these features, the respiratory system must provide two physiological
functions: (I) ventilation, the process by which ambient air is delivered to the alveoli
which are closely related to blood, and (II) gases exchange diffusion, defined as the
movement of oxygen and carbon dioxide in opposite directions across the alveoli and
capillary walls (11).
The respiratory system is divided into two sections according to these functions:
Upper Respiratory Tract and the Lower Respiratory Tract.
Figure 1. Respiratory System diagram.
26 Introduction
Upper Respiratory Tract included the Nasal cavity, Pharynx, and the Larynx. Its
primary function is to receive the air from the external environment and filter, warm,
and humidify it before it reaches the alveoli where gas exchange will occur (12).
The Lower Respiratory Tract is conformed by the tracheo-bronchial tree and the
lungs, both residing in the thoracic cavity. The airway is divided 23 times from the
trachea to the alveoli sacs, conforming an airway ramification comprised by the
bronchi and the smaller airways called bronchioles (13). Each bronchiole ends in an
elongated space enclosed by many air sacs called alveoli, which are surrounded by
blood capillaries. Therefore, the branching anatomic structure is ideal for maximizing
surface area to allow optimal gas diffusion or movement of gases across the alveoli.
In fact, there are 300 million of alveoli in a human (12).
Figure 2. Tracheo-bronchial tree diagram. Schematic representation of human
airways that depicts branching generations (G) beginning at the trachea (0) and
ending at the alveolar sacs (23). (Modified from reference [13]).
27 Introduction
2. Alveolar-capillary unit
The alveolar-capillary unit is highly specialized to maximize diffusion between
the blood and air gases. This alveolar-capillary structure is the most extensive in the
body. Specifically, the internal surface area of the adult lung is 70 to 80 m2, of which
90% covers the pulmonary capillaries; thus the air-blood surface available for gas
exchange is 60 to 70 m2
(14).
The alveolar-capillary unit is comprised of three major constituents: pulmonary
capillary endothelium, a mixture of cellular and extracellular interstitial components
and the epithelial lining of the alveolus composed by epithelial lining cells and a thin
layer of liquid covering the epithelial cells containing alveolar macrophages and
covered by pulmonary surfactant (15).
Figure 3. Schematic representation of the main parts comprising the alveolar-
capillary unit. (Modified from reference (1)).
28 Introduction
2.1. Pulmonary endothelium
The lung microvascular bed is the major collection of endothelial cells in the
human body (13). Alveolar capillary endothelial cells are large attenuated cells
adapted to facilitate efficient was exchange (13, 15), joined by tight junctions forming
a continuous, non-fenestratred, monolayer. Their luminal surface is in contact with
blood whereas their the abluminal surface rests on the endothelial basement
membrane containing type IV collagen in the lamina densa providing strength to
withstand rise in capillary pressure with exercise (15).
Ultrastructurally, endothelial cells had their nuclei usually oriented in the
direction of blood flow, lesser presence of intracellular organelles than other cell
types but a large number of plasmalemmal transport vesicles probably due to its role
in the transport of macromolecules (16).
In addition to its structural role as part of the alveolar-capillary membrane,
maintaining its integrity (17), pulmonary endothelium cells participate in the
regulation of blood flow, coagulation and fibrinolysis (18, 19). In fact, these cells
contribute to the regulation of pulmonary vascular tone by secretion of lipid mediators
or maintaining nitric oxide homeostasis (20). Furthermore, endothelium cells
participate in inflammatory reactions by its activation, facilitating leukocyte migration
from the blood into the alveolar airspace (21). Endothelial cells activation includes
changes in chemokine production and an increased of adhesion molecules expression
on the luminal surface of these cells in response to stimuli such as injury or infection,
leading to a dramatic increased of leukocytes migration (19).
Therefore, pulmonary endothelium possesses metabolic, structural, and
immunological functions that might be deregulated during injury.
29 Introduction
2.2. Pulmonary interstitium
The thinness and hydration state of the interstitial layer between the alveolus and
the endothelial cells is critical for a proper gas exchange. The pulmonary interstitium
comprises the extracellular matrix (ECM) and mesenchymal and immune cells such
as fibroblasts or interstitial macrophages. ECM is conformed by the interstitial
connective tissue and the basement membranes (BM) (22).
Alveolar interstitial connective tissue is mainly comprised by types I collagen,
type III collagen and fibronectin (22, 23).
On the other hand, basement membranes are condensed sheet-like structures
separating endothelial and epithelial cells from interstitial connective tissue.
In both rat and human lungs, the alveolar epithelial BM and alveolar capillary
BM have been shown to consist of highly cross-linked type IV collagen, laminin and
fibronectin (22, 23). This composition is thought to play a significant role in
preserving normal alveolar structure and function. Specifically, fibronectin is believed
to be involved in epithelial cell regeneration (24). Furthermore, a comparison of the
level and distribution of fibronectin expression in normal and fibrotic lungs supports
the hypothesis that fibronectin plays an important role in alveolar epithelial cell repair
(25).
Interestingly, the rat lung had two different interstitium morphologies according
to the thickness between the epithelium and the endothelium, suggesting a modulator
role of alveolar epithelial cell phenotype (26, 27). Specifically, it exist a thing area
where capillary endothelium and alveolar epithelium are separated by only a single
fused alveolar and capillary basement membrane, and thick areas, where endothelium
and epithelium are separated by their respective basement membranes and connective
tissue of the interstitial space (28).
Also, interstitial macrophages are quite prominent in the lung, constituting
approximately 40% of total macrophages in tissue (29). Due to their direct contact
with matrix and other pulmonary connective-tissue components, it is thought that the
release of mediators or enzymes by interstitial macrophages may have greater effects
than those released by macrophages in the alveolar compartment (30).
30 Introduction
2.3. Pulmonary epithelium
The alveolar epithelium is comprised of two morphologically distinct epithelial
cell types, the alveolar type I (ATI) and type II cells (ATII) (31), that are continuously
lined among terminal air spaces forming a barrier that is anatomically 1-cell thick
(32). Consequently, ATI and ATII cells form a tight barrier, which effectively
separates the alveolar air space from the vascular and interstitial spaces. However,
alveolar epithelium is an order of magnitude less permeable to small solutes than the
capillary endothelium (33). Thus, injury to the pulmonary epithelium increases
susceptibility to alveolar flooding (34).
Interestingly, morphometric studies have demonstrated that the distribution and
morphology of these cell types is remarkably analogous among mammalian species
including rat and human (35).
2.3.1. Alveolar epithelial type I (ATI) cells
ATI cells comprise only ~8-9% of the parenchymal cell population within the
lung, but cover ~95% of the alveolar surface (35, 36).
Morphologically, ATI cells are large squamous epithelial cells with widely
spread cytoplasmic extensions, small nucleus, few small mitochondria and
inconspicuous endoplasmic reticulum (ER) and Golgi apparatus (37). This
morphological adaptation provides a short diffusion path for gas exchange (36). ATI
cells are not metabolically active and are considered to be “inert” cells, mainly
providing a barrier function. However, there is accumulating evidence that ATI cells
contribute in active ion transport as well as are critical in maintaining alveolar fluid
balance and resolving air space edema (38).
2.3.2. Alveolar epithelial type II (ATII) cells
ATII cells comprise ~15% of lung parenchymal cells, but cover only ~3-5% of
the alveolar surface (35, 36). Typically located in the corners of alveoli, ATII cells are
cuboidal in shape, with apical microvilli and characteristic surfactant-containing
organelles known as lamellar bodies (35, 39). Known functions of ATII cells include
the synthesis, secretion and recycling of pulmonary surfactant (40), regulation of
alveolar fluid and electrolyte balance (41), host defense and immunomodulation (40).
In addition to their synthetic and secretory capacities, ATII cells function as the stem
cell of the alveolar epithelium and have a central role in alveolar epithelial repair (42).
31 Introduction
2.4. Pulmonary surfactant
As previously described, the alveolar epithelial cell surface is lined with a thin
fluid layer, denominated the alveolar lining layer, which is covered by a film of
pulmonary surfactant (PS) (15).
PS is a surface-active lipoprotein complex. The main function of PS film is to
stabilize the alveoli by the reduction of surface tension at the air-liquid interface,
preventing the alveolar collapse during end-exhalation (43). In addition, PS possesses
non-surface tension related functions such as host defense and pathogen barrier
functions, which makes PS physiologically essential (6).
Deficiency or dysfunction of PS causes severe respiratory diseases (6).
Specifically, the first pathology associated with PS alterations was the Neonatal
Respiratory Distress Syndrome (RDS) in the late 50s (44). This syndrome is
originated by an immaturity of the epithelium to synthesize and secrete a sufficient
amount of PS due to prematurity (45). Conversely, accumulation of PS in the alveolar
airspaces, as in pulmonary alveolar proteinosis, can be deleterious leading to gas
exchange impairment (46).
In addition, qualitative alterations of PS have been also involved in other
pathologies such as Acute lung injury (ALI) and its severe form, Acute Respiratory
Distress Syndrome (ARDS) (6, 46). These pathologies displays symptoms similar to
RDS but they can affect patients from any age, having mortality rates of ~30-40% (3,
47).
Therefore, research in PS biology in the past three decades leaded to open new
lines of study focused on the development of potential surfactant replacement
therapies (46). Hence, the study of PS has both physiological and clinical relevance.
2.4.1. Composition
Comparative biological studies suggest that PS exist in all air-breathing
vertebrates but with slightly composition differences (6, 48). However, PS
composition in mammals is outstandingly similar among species, i.e., approximately
90% lipids and 10% proteins by weight (wt.) (6, 49).
32 Introduction
2.4.1.1. Lipid composition
The lipids consist mainly of phospholipids (PL, ~90–95% wt.) with asmall
amount of neutral lipids (~5–10% wt.), primarily cholesterol (6, 50).
Interestingly, the most prevalent class of PL in PS is phosphatidylcholine (PC),
which accounts for ~80% of the total PL from most mammalian species. PC may have
either saturated or unsaturated acyl chains, whose length and saturation have an
impact on the fluidity of the lipid (51).
Although notable exceptions exist (52), in most cases ~40% of the PC is
dipalmitoylphosphatidyl choline (DPPC) (16:0/16:0 PC) (6). DPPC is a long-chained,
disaturated and zwitterionic (i.e. carry no net electrical charge) PL, mainly
responsible for reducing surface tension (γ) values to near-zero values upon film
compression. Despite its high capacity to reduce surface tension, DPPC does not
adsorb or re-spread to the surface quickly enough in vivo. At 37ºC, DPPC typically
exists in a gel phase, i.e., with its acyl chains in a rigid close-packed arrangement
Figure 4. Pulmonary Surfactant composition diagram. PL: phospholipids; PC:
phosphatidylcholine; PG: phosphatidylglycerol; DPPC:
dipalmitoylphosphatidylcholine; SP-A, SP-B, SP-C and SP-D: pulmonary surfactant
protein (SP) -A, -B, -C, -D.
33 Introduction
allowing to form a condensed monolayer upon compression and resisting high surface
pressures (50).
In contrast, unsaturated lipids at 37ºC exist in a liquid crystalline phase and
cannot form a condensed monolayer in a highly compressed state. These lipids are
more fluid-like because of the double bond. Therefore, the presence of unsaturated
lipids in PS helps in fluidizing and re-spreading DPPC and other saturated lipids (51).
Other PL classes that are also present in lung surfactants but in minor proportion,
include phosphatidylethanolamine (PE), phosphatidylglycerol (PG),
phosphatidylinositol (PI), phosphatidylserine (PS) and sphingomyeline (SM). These
lipids also help in the adsorption and re-spreading of DPPC. At physiological pH, PC
PE or SM are zwitterionic, while PG, PI and PS are anionic or negatively charged (6).
Anionic PL as a group accounts for ~15%of the total PL and have been shown to
interact with the cationic surfactant protein B and C, being critical for the proper
functioning of PS at the air/alveolar liquid interface (53).
Finally, neutral lipids constitute 10% wt. of the PS with cholesterol accounting
for approximately 80-90% wt. Its main function resides in its ability to maintain the
balance between fluidic and rigid lipid phases in PS (51).
2.4.1.2. Protein composition
Besides the aforementioned lipidic components, four surfactant proteins (SPs) are
also present in PS. They are named pulmonary surfactant protein (SP)-A, -B, -C and -
D, based on the nomenclature proposed by Possmayer (54).
Interestingly, SPs can be separated in two groups according to their role
accomplished in the PS system as active inhibitors of a broad spectrum of foreign
pathogens or as regulators of the interfacial surface tension (55).
Hence, the first group are large hydrophilic SPs, SP-A and -D, are members of a
family of collagenous carbohydrate binding proteins, known as collectins, or calcium-
dependent (C-type) lectins. Collectins consist of oligomers of trimeric subunits, which
are able to recognize, inhibit and inactivate a wide range of foreign pathogens (55).
Conversely, the small molecular weight hydrophobic SPs, SP-B and-C, are tightly
associated with PS film at the air–liquid interface contributing to regulate the
structure, integrity and composition of the surface lipid film (6, 55-57).
34 Introduction
Among these PS-associated proteins, SP-A is the most abundant by mass (but not
by molar ratio), accounting for ~5% wt. of PS, with SP-D, accounting for ~0.5% and
SP-B and SP-C constituting together approximately~1-1.5% (58).
Collectins
SP-A
SP-A (630 kDa) is a large multimerichydrophilic glycoprotein consisting of 18
subunits, each weighing 28-36 kDa conformed by four structural domains (59):
(I) N-terminal segment involved in intermolecular disulfide bond formed by 7–10
amino acids.
(II) Collagen-like domain formed by 79 residues characterized by 23 Gly-X-Y
repeats with an interruption near the midpoint of the domain of Pro-Cys-Pro
sequence that is responsible for the formation of SP-A characteristic supra-
quaternary structure (59, 60). The collagen-like domain of mammalian SP-A
functions as scaffolding that amplifies the ligand binding activities of globular
domains. Moreover, collagen-like domain is responsible for the binding of SP-
A to some receptors on the surface of alveolar macrophages and epithelial
cells (61).
(III) Neck region located between the collagen and the globular domain conformed
by a 35 amino acid segment with high -helical propensity.
(IV) C-terminal globular domain composed by 115 residues, including four
conserved cysteins that form two intra-molecular disulfide loops and 18 highly
conserved amino acid residues common to C-type leptines. The basic structure
of the globular domain consists of a structural core conformed of –helical
and –strands (59). This conformational shift enhances lipid binding and
allows Ca2+
-dependent binding of oligosaccharides, protein self-association
and SP-A-mediated lipid aggregation (59, 61, 62).
The human SP-A locus consists of two similar but non-identical genes, SP-A1
and SP-A2, each approximately 5 kb in length and a truncated and nonfunctional
pseudogene that shares 85% similarity with the SP-A 3´ untranslated region (63);
however in other mammals such as rats (64) there is a single-copy gene.
35 Introduction
The human SP-A locus has been assigned to chromosome 10q22-q23 near the
loci for SP-D and MBP, suggesting that this area of chromosome 10 is involved in the
evolution of collagenous C-type lectins (63). Recently, it has been found that SP-A1
and SP-A2 are in linkage disequilibrium, indicating close physical association. In fact,
it has been detected opposite transcriptional orientation suggesting that both genes
might share cis-acting regulatory elements (65). Indeed, it is thought that both gene
products are expressed in a 2:1 ratio (SP-A1:SP-A2) and associated through their
collagenous domains to form heterotrimers (66).
SP-A is modified after translation in the ER and Golgi (cleavage of the signal
peptide, proline hydroxylation, and N-linked glycosylation) and assembled into a
complex oligomeric structure that resembles a flower bouquet (59, 61, 62). SP-A
assembly is an intracellular process that can be conceptualized in two parts: the
folding of monomeric subunits into trimers (Figure 5a) and the association of six
trimers into an octadecamer (59) (Figure 5b). Interestingly, mammalian SP-A is not
only assembled in supratrimeric oligomers but also forms multimers by self-
association of the protein in the presence of Ca2+
.
Supratrimeric oligomerization and multimerization of mammalian SP-A seems to
be needed for many of its functions, such as host defense and immunosuppressive SP-
A high-affinity binding capabilities (to lipids, carbohydrate-bearing surfaces, and
proteins ) (59).
Figure 5. Models of trimeric (a) and oligomeric (b) forms of SP-A. All human SP-A
structural domains are depicted: I) NH2-terminal segment; II) collagen-like domain with a
sequence irregularity, which divides the collagen-like domain in two parts; III) neck
region; and IV) COOH-terminal globular domain. (Figure modified from reference [55])
36 Introduction
SP-A participates in alveolar innate immune defense, together with SP-D and
other proteins and peptides, by direct killing of microorganisms or by indirect killing
through enhancing the uptake of pathogens by phagocytes (55).
SP-A can bind to some micro-organisms such as Gram negative bacteria (67),
that may lead to either bacterial killing and/or bacterial aggregation. Bacterial
aggregation facilitates phagocytosis mediated by the collagen tails of SP-A, initiating
a proinflammatory response (61). As well, SP-A contributes to phagocytosis of some
virus like respiratory syncytial virus, influenza virus A or herpes simplex virus type 1
(68-70).
Also, SP-A binding to receptors results in an antiinflammatory response (71, 72)
and prevents the persistence of inflammation, which is detrimental to the lung. For
example, SP-A regulates signaling pathways in macrophages in response to microbial
recognition that controls inflammation like toll-like receptor-2 (TLR-2) signaling
pathway (73). As well, SP-A binds to various receptors of ATII cells including P63
(74) and SPAR (75), to activate the phosphatidylinositol 3-kinase (PI3K) pathway
triggering in last term the expression of pro-inflammatory genes (75).
Finally, SP-A is mainly associated with PS and has some properties related to
its ability to bind and aggregate PS membranes:
(I) Together with SP-B, contributes to the formation of tubular myelin.
(II) Improves the rate of surfactant adsorption to an air–liquid interface.
(III) Protects PS membranes against inactivation by transudated serum proteins
(59, 62).
SP-D
As SP-A, SP-D (520 kDa) is also a member of the family commonly known as
collectins that are involved in the first line of defense against fungal, bacterial, and
viral infections (76).
SP-D as other collectins is assembled as oligomers of trimeric subunits,
specifically formed a cruciform structure in which four homotrimeric subunits self-
associate at their N-termini to form highly ordered SP-D dodecamers (Figure 6b).
Each subunit (43 kDa) consists of four regions (Figure 6a): (I) a short N-terminal
non-collagen sequence; (II) a very long collagen domain of 59 Gly-X-Y repeats; (III)
37 Introduction
ashort linking domain, the „neck‟ region that connects the collagen domain to the
fourth region; and (IV) C-terminal carbohydrate recognition domain (CRD) (55).
Some studies suggested that folding of the CRD, trimerization of monomers,
triple helix formation, the amino-terminal association of trimeric subunits and the
formation of inter-chain disulfide cross-links occur in the rough ER whereas
oligosaccharide maturation occurs in the Golgi immediately prior to secretion (77).
As previously described, SP-D gene have been localized in the region of
10q22.2–23.1 close to SP-A (63, 76). Conversely, a single gene encodes human SP-D.
However, protein, cDNA, and genomic sequencing together suggest the existence of a
number of SP-D alleles, some of which are characterized by amino-acid substitutions
in the coding region. Therefore, the SP-D gene encodes at least one, and probably
two, untranslatedexons at the5´-end of the gene, similar to SP-A (76).
SP-D plays complex role in innate immunity in the alveolus by decreasing
inflammation and promoting clearance of pathogens from the respiratory tract without
stimulating a secondary immune response. The functions of SP-D have been
investigated at different levels according to the interaction between effector cells and
pathogens.
Figure 6. Models of trimeric (a) and oligomeric (b) forms of SP-D. All structural
domains of SP-D are represented: I) NH2-terminal segment; II) collagen-like domain; III)
neck region; and IV) COOH-terminal globular domain.
38 Introduction
First, SP-D binds to carbohydrate structures of several pathogens such as
influenza A virus, a variety of gram-negative bacteria including Klebsiella
pneumoniae, Pseudomonas aeruginosa, Hemophilus influenzae, and Escherichia coli
or opportunistic fungal pathogens such as C. neoformans, Aspergillus fumigatus
conidia and Candida albicans, leading to their inhibition (76-79).
Second, SP-D binds to leukocytes such as alveolar macrophages and dendritic
cells modifying their activities by: (I) opsonization or other effects mediated by the
specific interactions of the leukocyte with SP-D-coated organisms; (II) direct effects
of SP-D on phagocyte function; and (III) SP-D-mediated alterations in particle
presentation secondary to aggregation (77).
However, all these mechanisms may be operative, alone or in combination, in
specific microbial-phagocyte interactions.
Also SP-D−/− knockout mice show that they have impaired host defense upon
injury or infection instead of an exaggerated inflammatory response, heightened
susceptibility to inflammatory stimuli, infections or allergic sensitization (55).
Furthermore, immune cells in the lung of SP-D−/−mice display multiple
abnormalities including altered morphology and constitutive release of pro-
inflammatory mediators (55).
Hydrophobic peptides
SP-B
Though SP-B comprises only~10% (w/w) of SPs, its absence or dysfunction due
to mutations results in respiratory failure and death shortly after birth (80).
Human SP-B mRNA is produced from a single gene located on chromosome 2 at
a site syntenic with the murine SP-B gene located on chromosome 6 (81, 82). The SP-
B gene is first transcribed/translated into a significantly larger monomeric pre-pro-
protein of approximately 42 kDa,which is processed to a smaller, lipid-associated
peptide in the distal secretory pathway within the type II cells (46, 83).
The monomeric pre-pro-protein is first N-glycosylated on regions flanking the
mature SP-B sequence (83). These flanking arms are cleaved at several steps among
trans-golgi, multi-vesicular bodies (MVB) and proximal lamellar bodies (LB) where
proteases such as napsin A, cathepsin H and pepsinogen C are involved (46, 83).
39 Introduction
Once finishing the protein processing, the mature form of SP-B results in a 79
amino acid homodimer of approximately 18 kDa (84), contained in the LB of the
secretory pathway of ATII.
Analysis of the sequence of SP-B reveals that this protein belongs to the family
of the saposin-likeproteins. Each SP-B monomer (9kDa) possess small folds of
around 80 amino acids containing amphipathic alpha-helices and three intramolecular
disulfide bridges that link Cys-8–77, Cys-11–71, and Cys-35–46 (85, 86). The
remaining cysteine at position 48 establishes the intermolecular bond responsible for
dimerization of SP-B that does not take place until the cleavage of the flanking arms
is completed. This bond is a disulfide linkage that presumably constrains the protein‟s
flexibility and contributes to the remarkable thermal stability of the secondary
structure (87) and the unusual resistance to both acid and proteolytic degradation.
Although it still lacks a three-dimensional model of the structure and disposition
of SP-B in surfactant membranes, it has been proposed that SP-B interacts
superficially with the surface of bilayers and monolayers, through amphipathic helical
motifs (88).
Figure 7. Models of the homodimer of SP-B (a) and its models of interaction with
lipid monolayers (b) and bilayers (c).
40 Introduction
In fact, all saposin-likeproteins have activities related to interacting with and
inserting todifferent extents into PL membranes (85), but SP-B is the only member of
the family that is permanently membrane-associated, partially due to its high
hydrophobicity (56). Also the net positive charge of SP-B likely promotes a certain
selective interaction of SP-B with the anionic PL fraction of surfactant, and
particularly with PG (89) though there is a certain controversy due to whether SP-B
prefers PG-enriched or PC-enriched membrane regions (90). Conversely, it has been
established that SP-B is distributed specially in disordered regions of membranes and
interfacial films (56).
Therefore, SP-B facilitates organization of PS membranes in the lamellar body,
likely through its ability to promote membrane-membrane contacts, perturbation of
lipid packing, and membrane fusion (46). Furthermore, SP-B promotes a rapid and
efficient adsorption of surfactant PL into the air–liquid interface and modulates the
stability and dynamic behavior of interfacial surfactant films subjected to continuous
compression–expansion cycling (45).
On the other hand, SP-B deficiency, arising from mutations in the human gene
(SFTPB) or disruption of the mouse locus (Sftpb), results in vesiculated LB with few
or no bilayer membranes and electron dense inclusions (46). Most importantly, severe
SP-B deficiency (i.e., ~75% reduction in SP-B content in the airspaces) results in fatal
RDS (91). Indeed, SP-B expression is altered in several acute and chronic lung
diseases contributing to their pathogenesis (80).
SP-C
SP-C (4 kDa) is a non-homologous protein considered the most specific protein
in terms of biophysical activity of PS and tightly linked with lung differentiation in
mammals (56). Surprisingly, animals lacking expression of a functional SP-C are able
to breath and therefore survive (92), suggesting that the action of SP-C is not as
critical as SP-Bs. However, deficiencies in SP-C are irretrievably associated with
severe respiratory pathologies (80).
Human SP-C gene is organized into six exons and is localized in the short arm of
chromosome 8 (93). Differential splicing of the primary transcript, localize primary at
5´and 3´of exon 5, leads to several SP-C RNAs, but the SP-C RNA of ~0.9 kb
encodes a pro-protein of 197 amino acid in human or 194 amino acids in rat (93-95).
41 Introduction
Like SP-B, SP-C is first synthesized as a pro-protein. During its biosynthesis, the
transmembrane segment of proSP-C, which will be afterwards the main part of the
mature protein, is oriented with its N-terminal end exposed to the cytosol and the C-
terminal side to the lumen of the ER (95).
The cytosolic domain encodes information required for intracellular trafficking of
SP-C to the MVB/LB compartments (96). Here, assembly of SP-C into PS
membranes is coupled with proteolytic processing of proSP-C precursor, to liberate
N-terminal and C-terminal propeptides (46). Specifically, the generation of the 35-
amino acid mature peptide involves a removal of 23-25 residues of N-terminal pro-
peptide and 133-139 residues from the C-terminus of the pro-protein (94). Also, SP-C
is post-translationally modified by addition of palmitoyl groups via thioester bonds to
Cys-5 and Cys-6 (97). Interestingly, it is suggested that the processing machinery of
SP-C maturation might be shared with SP-B as cathepsin H seems to be implicated
(96).
Subsequently, fusion of the MVB with a LB leads to SP-B-mediated
incorporation of SP-C-containing luminal vesicles into existing PS membranes that
are eventually secreted into the airspaces. Thus the highly hydrophobic mature SP-C
maintains its transmembrane orientation throughout biosynthesis (46).
As a result, mature SP-C is a small hydrophobic lipopeptide of 35 amino acids,
containing palmitoylated cysteines, which is co-purified with SP-B and PL in
chloroformic extractions of PS (98). Its three-dimensional structure consisted in a
rigid α-helix covering approximately two thirds of the sequence and an unstructured
N-terminal segment containing palmitoylated cysteines (97) (Figure 8a). In
membranes, the helical segment of SP-C adopts a transmembrane orientation, adapted
to traverse the DPPC bilayer in a fluid state(46) (Figure 8b and c).
SP-C, with lower activity that SP-B, is also able topromote adsorption and
transfer of PL into the air–liquid interface (99).
Also, it has been suggested that SP-C could contribute to the remodeling of
composition and structure of the interfacial films due to its exclusion of the
monolayer during compression together with its intrinsic ability to interact and disrupt
PL membranes with both α-helical segment, and N-terminal regions (100-102).
Furthermore, it has been detected that SP-C promotes the formation of multilamellar
structures associated with interfacial films during compression of surfactant films
42 Introduction
(103). For that purpose, the presence of palmitic acid chains esterifying the cysteines
in the N-terminal segment of the SP-C molecule seems to be critical to maintain this
association (104).
On the other hand, increasing evidence indicate that SP-C is also involved in
immunomodulation that is critical for the stability and host defense of the airways
(80). Interestingly, SP-C-deficient mice were found to be susceptible to bacterial and
viral infections showing excessive inflammation (105, 106) and more vulnerable to
develop severe outcomes in bleomycin-induced fibrosis (107).
A well, several studies observed that the amino-terminal segment of SP-C binds
LPS suppressing inflammation (108-110) and SP-C-containing surfactant vesicles
bind and interfere with toll-like receptors mediating the inflammatory responses in
macrophages (105).
Figure 8. Model of the monomer of SP-C (a) and its models of interaction with
lipid monolayers (b) and bilayers (c). Nt: Amino-terminal region; palmitoyl groups
bonded to Cysteine (Cys) 5 and 6 are indicated with black arrows. Ct: Carboxyl-
terminal region.
43 Introduction
2.4.2. Metabolism
ATII cells are mainly responsible of the synthesis, storage, secretion, and even
recycling of almost all components comprising PS. Here we divided the metabolism
of PS in three sections: Synthesis and processing; Secretion; and Recycling and
turnover.
2.4.2.1. Synthesis and storage
The PL and proteins of PS are synthesized in ATII cells, assembled in lamellar
bodies and extruded into the alveolar lumen by exocytosis.
Phospholipids synthesis
As SPs synthesis and processing has been mentioned in the last section, here we
briefly summarize the synthesis of main important lipids of PS.
Figure 9. Diagram of the metabolism of pulmonary surfactant. ATI: alveolar type I
cells; ATII: alveolar type II cells; E.R.: endoplasmic reticulum; MVB: multi-vesicular
bodies; LB: lamellar bodies.
44 Introduction
Phospholipids are composed of a glycerol backbond, two fatty acids and a polar
phosphorylated moiety. This composition conferred to the PL amphipathic properties.
The fatty acids required for PS lipid synthesis might be recruited from circulation as
free fatty acids or triacylglycerols in lipoproteins but also might be synthesized de
novo by ATII cells from several precursors such as glucose, lactate or acetate (111).
All diacylglycerol phospholipids are synthesized in the ER through a chain of
biochemical events beginning with the formation of phosphatidic acid, which is
hydrolyzed to diacylglicerol. Subsequently, specific enzymes transform this product
generating compounds with several polar heads, like PC, PG or PI (112).
Interestingly, as previously mentioned, half of the PC in PS is DPPC, accounting for
~40% of total surfactant PL (6). Two pathways contribute to the production of DPPC,
de novo synthesis andremodeling via lysoPC. However, the latter pathway accounts
for up to 75% of DPPC in ATII cells and involves deacylation of unsaturated PC at
the sn-2 position by a Ca2+
-dependent phospholipase A2 (14, 46).
The regulation of PL synthesis in the lung is influenced by developmental and
hormonal factors affecting several rate-limiting metabolic steps. Corticosteroids and
thyroid hormones enhance the activity of several enzymes within the PL synthetic
pathway whereas insulin, epithermal growth factor (EGF) or transforming growth
factor (TGF-) influence PS production (112, 113). Interestingly, some of these
factors e.g. glucocorticoids, are directly involved in the control of AMPc production,
which in last term regulate SP levels (114, 115).
Storage
Pulmonary surfactant complexes are assembled in ATII cells and stored in form
of tightly packed membranes in the LBs (e.g. the characteristic storage granules of PS
in ATII cells) (Figure 10) (116). They consist of a limiting membrane surrounding
about 20-70 tightly packed PL bilayers, or lamellae, arranged in a hemisphere (117,
118). These organelles belong to the endosomal–lysosomal pathway and their
maturation requires proper trafficking of proteins and lipids along the regulated
exocytic pathway (119).
As previously mentioned, it has been postulated that SP-B and SP-C are
synthesized in the ER and processed through the Golgi and MVBs reaching LBs
(120). Conversely, though SP-A is also synthesized and processed in ER and Golgi,
45 Introduction
now it is widely accepted that it is secreted into the extracellular media by a different
pathway and probably interacts with PS membranes once in the alveolar space (121).
As well, the major surfactant PLs are synthesized in the ER. Three pathways of
intracellular lipids transport has been postulated: vesicular transport, non-vesicular
transport, and diffusion at membrane contact sites (122).
Vesicular transport plays an important role in trafficking newly synthesized SPs
andis also important for recycling of PS proteins and lipids via the endocytic pathway.
However, though there are some evidences of PS lipids vesicular transport from the
ER to the LB (123) a separate study found that inhibition ofvesicular transport did not
inhibitincorporation of newly synthesized lipid intothe LB (124).
The non-vesicular transport pathway can answer these results due to the
localization of the ABC transporter (ABCA3) to the limiting membrane of the LB
(125, 126). Indeed, as ABC transporters typically move substrateout of the cytosol,
Figure 10. Ultrastructural appearance of alveolar epithelial type II cells by electron
microscopy (bar=0.2m). Lamellar bodies (LB), nuclei (N), mitochondria (M), alveolar
lumen (AL), capillary (CA). (Image from Fehrenbach et al. Respiratory Research 2005.)
46 Introduction
being liable that ABCA3 would be an essential transporter of PL into the LB. In fact,
disruption of the Abca3 locus results in neonatal lethal RDS associated with loss of
LBs (127, 128).
Another postulated mechanism for PL transfer from ER to LBs is via diffusion or
facilitated exchange at membrane contact sites that would require the participation of
accessory proteins to ensure the formation of transient contact sites between the
appropriate donor (ER) and acceptor (LB) organelles (122). However, these pathways
remain as an important and unresolved question.
There are several classes of LBs according to their packaging statement from
round–concentric-like membranes to very tightly packed piles of membranes (56).
These types areusually linked with the proximity with the alveolar surface. Thus,
when LB acquired the final packed state, they are found near the alveolar surface to
be extruded into the alveolar lumen by exocytosis.
2.4.2.2. Secretion
PS secretion requires the transportation ofLB to the apical membrane of ATII
cells. According to several stimuli such as cholinergic and -sympathomimetic
agents, Ca2+
ionophores, purine agonists and the most important, alveolar stretching,
the limiting LB membrane is merged with the plasma membrane of ATII cell,
extruding the LB into the hypophase (e.g. thin aqueous layer covering the ATII cell
surface) by exocytosis (Figure 11a) (129, 130).
In the hypophase, the tightly packed surfactant membranes comprising the LBs
tend to reorganize to form a loose network of interconnected membranes named
tubular myeline (TM) (Figure 11b). It is not clear how the structural transformation of
surfactant membranes is triggered, but potential effectors include changes in the
hydration of surfactant complexes, pH, presence of surfactant apoproteins or calcium
concentration (50–52).
47 Introduction
TM is composed of large square elongated tubes, constituted primarily of PL
(DPPC and PG), proteins SP-A and SP-B, and Ca2+
(6), ranging in size from
nanometers to microns (53,54). Membranes in TM arrange in an ordered pattern,
whose dimensions are related with the molecular size of SP-A macromolecule,
suggesting that SP-A is the main determinant for TM organization. Though the
mechanisms of TM are still under discussion, it is likely that TM formation requires:
(I) close contacts between opposing DPPC-rich membranes mediated by SP-A; (II)
SP-A self-association mediated by Ca2+
, and (III) membranes fusion mediated by SP-
B (59). As SP-A is mainly implicated in innate defense (59), current thinking assumes
that TM structure plays also some role in optimizing clearance of pathogens.
Subsequently, PS components of TM are transferred to form a surface-active film
at the air–water interface of alveoli by rapid adsorption. In this case, SP-B and SP-C
are thought to facilitate PL transfer (specifically DPPC) from TM to the surface film
(56, 58).
Figure 11. Electron micrographs sections (bar=0.1 m). a) A lamellar body in the
process of exocytosis from a type II cell. (Figure from reference [122]). b) Lamellar bodies
(LB) are seen forming tubular myelin (TM). Inset: detail of tubular myelin showing small
projections in the corners, thought to represent SP-A (Image from reference [34]).
48 Introduction
Traditionally, the PS film has been considered to be a monolayer (131, 132).
However, several studies using different techniques (133-136) conclude that at least
part of the PS film is thicker than a single monolayer. Specifically, plus the surface
monolayer, there are at least one lipid bilayer closely and apparently functionally
associated with the interfacial monolayer (Figure 12). These multilayers structures
could provide additional stability to PS monolayers, thereby allowing the attainment
of very low surface tension (6).
Therefore, upon compression of the PS film during expiration, SPs induce the
formation of unsaturated phospholipids-rich multilayers that remain associated with a
monolayer enriched in saturated PL species. After inspiration, some of the lipids in
the reservoirs are re-adsorbed into the surface film, helped by the hydrophobic
peptides in order to avoid significant loss of material (57).
Figure 12. Diagram of a multilayer interfacial surfactant film structure.
It depicted the possible interaction between pulmonary surfactant-associated proteins
with the monolayer in the air-liquid interface and the bilayers associated.
Yellow: SP-C; Red: SP-B; and Green: SP-A.
49 Introduction
2.4.2.3. Recycling and turnover
Compression-expansion cycling during respiration leads to progressive
conversion of the surface-active fractions of PS into lesser active lipid/protein
complexes (46). The inactivation of PS may result from detachment of small PS
particles from the air-liquid interface, changes in lipid/protein association, and
oxidation of lipid and protein species of PS without rejecting the possibility of
inactivation byincorporation of materials inhaledfrom the upper airways (6, 137).
Maintenance of a fully functional surfactant film therefore requires continual film
refinement through efficient removal of spent PS and incorporation of newly secreted
complexes (46).
These lesser active PS complexes are small vesicular forms named small
aggregates (SA) that represent used PS destined for clearance and re-uptake. These
aggregates can be separated by centrifugation of lung lavage fluid from the fraction of
heavy, large aggregates (LA) forms containing more surface active material i.e.
tubular myelin, lamellar bodies and proteins (138). Measurement of aggregate
conversion is used experimentally to estimate PS inactivation, being correlated the
increment of SA with lung injury (139, 140).
SA is continuously taken up by ATII cells for recycling or, toa lesser extent (5-10
% of total), cleared by alveolar macrophages (141) (Figure 13). However, it has been
demonstrated that alveolar macrophages depletion significantly affects PS metabolism
(142).
The surfactant lipids that are recycled back into the ATII cells can either be
catabolized for the novo lipogenesis in lysosomes or reutilized intact in the LB were
the biosynthetic and endocytic pathways converge. The estimated turnover period of
PS range from 4 to 11h (143).
50 Introduction
2.4.3. Functions
The main functions of PS system are: (I) reduce the surface tension in the
alveolar air-liquid interface; (II) Alveolar-capillary fluid homeostasis maintenance;
and (III) Host defense against pathogens and inflammation. These functions can be
accomplished by the whole PS system or specifically by one of its components.
2.4.3.1. Surface tension reduction in the alveolar air-liquid
interface
Molecules at an interface between two phases, like the alveolar air-liquid
interface, are subjected to specialized conditions that generate associated forces
manifested as surface tension (144).
Specifically, because liquid molecules at the interface have strong attraction
toward the bulk of the liquid (i.e. water is a strongly polar substance with a significant
intramolecular attractive forces) with no equivalent forces above the surface because
air molecules are dilute, this imbalance leads to minimize surface area of the alveoli,
raising the surface tension (144).
Figure 13. Diagram of recycling and turnover of pulmonary surfactant LA: large
aggregates or functional fraction of pulmonary surfactant; SA: small aggregates or
inactive fraction of pulmonary surfactant; LB: lamellar bodies.
51 Introduction
PS is a surface-active lipoprotein complex which has energetic preference to the
interface due to its amphipathic condition. As a result, PS film ubication at the
alveolar air-liquid interface decrease the net unbalanced attractive forces between
interfacial region and bulk liquid molecules, lowering surface tension (51).
The resulting PS surface film is compressed and expanded during breathing and
lowers and variances surface tension in a dynamic way. As alveolar size decreases
during exhalation, PS film is compressed and surface tension reaches very low values
(<1 mN/m compare with 70 mN/m for pure water at 37ºC). Conversely, when
alveolar size increases with inspiration, the PS films is expanded, and surface tension
proportionaly increases (~23 mN/m at 37ºC). This dynamic variation of surface
tension with area allows alveoli of different sizes to coexist stably at fixed pressure
during respiration (51).
Therefore, idealicing the alveoli shape as spherical cavities, it can be applied the
Laplace-Young law which enounces that the pressure () inside the alveoli is directly
proportional tosurface tension () and inversely proportional to alveolar radius (r).
As a result, small alveoli resist collapse at end expiration because their surface
tension is low, and alveolar inflation is better distributed during inhalation because the
ratio of surface tension to area is more uniform in different-sized alveoli (Figure 14)
(51).
Moreover, by reducing surface tension throughout the lungs, PS decreases the
pressures (work) needed fot pulmonary inflation. Interestingly, there is a direct
conection between the surface activity of PS and pulmonary pressure-volume
mechanics. The physologic consecuences of PS deficiency or dysfunction includes
atelectasis, uneven inflation and severe ventilation/perfusion alterations present in the
lungs of preterm infants with RDS (144).
52 Introduction
2.4.3.2. Alveolar-capillary fluid homeostasis
PS also plays a role in homeostasis maintenance of the alveolar fluid, thereby
preventing edema formation. Edema is defined as an abnormal accumulation of fluid
in the interstitium followed by fluid compilation in the alveolar space.
The net flow fluid (Q) across the alveolar-capillary membrane is generally
expressed using the Starling equation:
Q=Kf ([Pc-Pi]-R[c-i])
Therefore the net fluid movement between compartments is determined by six
factors:
1) The filtration coefficient (Kf): is the constant of fluid permeability of the capillary
wall. Therefore, a low value indicates a low capillary permeability whereas a high
value indicates a highly water permeable capillary typical of several damages like
ARDS.
2) The hydrostatic pressure difference across the capillary, which is determined by the
difference between the capillary hydrostatic pressure (Pc) and the interstitial
hydrostatic pressure (Pi, which is negative).
Figure 14. Surface tension in the alveolar air-liquid interface. a) Law of Laplace-
Young illustrated. The small alveoli tend to empty into the large one in order to balance
the pressure difference between them. b) Alveoli with presence (normal state) and absence
(collapse state) of pulmonary surfactant. pressuresurface-tension; r: ratio.
53 Introduction
3) The reflection coefficient (R) is used to correct the magnitude of the oncotic
pressure gradient taking into account the efficiency of the capillary wall to prevent
protein leakage. It can have a value from 0 to 1, being 0 total protein leakage and 1
absence of protein flow.
4) The oncotic pressure difference across the capillary, which is assessed by the
positive difference between plasma colloid oncotic pressure (c) and interstitial
colloid oncotic pressure i).
Therefore, under normal conditions, the balance of Starling forces across the
alveolar-capillary membrane favors a net flow of fluid out of the microvascular space
into the interstitium (145, 146).
The resulting small net filtration is balanced by lymphatic drainage of the
interstitium, which also contributes to the subatmospheric pressure in the interstitial
spaces, favoring fluidfiltration. However, an excess of fluid accumulation in the
interstitium leads to fills progressively the alveoli (145).
Figure 15. Diagram of the forces implicated in the net flow of fluid from the
capillary to the interstitium. Pc: capillary hydrostatic pressure; Pi: interstitial
hydrostatic pressure; c plasma colloid oncotic pressure;i: interstitial colloid
oncotic pressure.
54 Introduction
PS contributes to maintain constant the negative levels of Pi by keeping intra-
alveolar pressures due to its action of decreasing surface tension and alveoli area
proportionally during expiration. Consequently, PS inactivation results in a surface
tensionincrement causing a reduction in the negative value of Pi, altering the
hydrostatic pressure difference and consequently increasing the net fluid movement to
the interstitium and subsequently to the alveolar space (147). Interestingly, intra-
alveolar edema promotes PS inactivation triggering ALI, leading to a damaging
feedback.
2.4.3.3. Innate host defense
PS is involved at several levels in host defense mechanisms:
Physical barrier: The alveolar epithelium is a potential pathogens gateway as it is the
greater surface contact of the organism with the environment. Consequently, the
inhaled pathogens that manage to evade the defense mechanisms of the upper
airwaysface PS. Thus, PS is the first defensive barrier at the alveolar space hindering
the adhesion of the incoming particles to the alveolar epithelium and facilitating their
removal through mucocilliary transport (148).
Inhaled particles interaction: PS-collectins SP-A and SP-D mainly accomplish this
function (see section 2.4.1.2). Both collectins are able to bind a wide range of ligands
including allergens, LPS and other surface molecules of bacteria, virus or fungi (148).
As a result, the complex pathogen-collectin can be eliminated either directly by
enhancing the membrane permeability (149) or indirectly by improving the
aggregation, opsonization and clearance of these pathogens via leukocytes (55, 148).
Immunomodulatory interaction with leukocytes: Almost all components of PS are
able to accomplish immunomodulatory activities.
Recent studies have illuminated a potentially important roleof surfactant PL in
altering the immune response. PL, specifically anionic lipids appear to act as
immunosuppressive mediators by inhibiting responses such asrelease of reactive
oxygen species and proinflammatory cytokines (80, 148). Specifically, phosphatidil
glycerol (POPG) attenuates or even blocks TLR-2 and TLR-4-dependent
inflammatory processes and prevent infection of some virus (150, 151). Also,
55 Introduction
dipalmitoylphosphatidyl glycerol (DPPG) inhibit viral infection by blocking
attachment of the virions to host cells (152). On the other hand, DPPC, the major PS
phospholipid, blocks epithelial cell expressed TLR4 activation by limiting
translocation of TLR-4 to membrane lipid raft micro domains (153) and induced
expression of several macrophage innate immune receptors (154).
As well, some studies suggested that the hydrophobic peptides SP-B and SP-C
have an inmunomodulatory role (148) (see section 2.4.1.2). SP-B-deficiency is
suggested to impair the ability of the lung to counteract LPS-induced inflammation
and promotes an inflammatory status mediated by alveolar macrophages and ATII
cells (155, 156). On the other hand, SP-C may be involved in host defense as it
interacts with both LPS and the pattern recognition molecule CD14 found on
phagocytes to reduce it response (88, 110, 157).
Additionally, collectins can also modulate the host inflammatory response
independent of activities against microbial agents. Specifically, SP-A and SP-D play a
major role regulating inflammation by hastening the clearance of apoptotic cells and
impeding the release of cytokines and other proinflammatory products. Moreover,
some experiments depicted that SPA or SP-D knockout mice, have increased the
presence of proinflammatory cytokines and inflammatory response resulting due to
infection (55).
2.5. Pulmonary immune system
The lung is constantly exposed to environmental pathogens, allergens and
toxicants. Therefore, this system had developed robust defenses to protect itself
against the deleterious effects of such challenges (158). The mechanisms of
pulmonary defense can be divided into non-specific defenseandspecific defense
accomplished by the innate immune system.
Non-specific defenses are mechanisms of physical removal such as cough and
expectoration, lymphatic flow from the alveolus to the lymph nodes, and mucociliary
clearance (158). The innate immune system includes soluble factors like proteins that
bind to microbial products and leukocytes that ingest particulates and kill
microorganisms (159).
The soluble constituents of airway and alveolar fluids have acritical role in the
innate immune defense in the lungs. There are a wide range of soluble factors in the
56 Introduction
alveolar and airway aqueous fluids accomplishing this role suchlysozyme, which is
lytic to many bacterial membranes; lactoferrin, which excludes iron from bacterial
metabolism; IgA and IgG, being IgG the most abundant immunoglobulin in alveolar
fluids (160); defensins, which are antimicrobial peptides released from leukocytes and
respiratory epithelial cells (161); LPS-binding protein (LBP) and soluble CD14
(sCD14), which are key molecules in the recognition of LPS by alveolar macrophages
and other cells in the alveolar environment (162, 163); and complement proteins and
surfactant-associated proteins (SP-A and SP-D) that serve as additional microbial
opsonins (see sections 2.4.1.2 and 2.4.3.3).
Cellular innate immune mechanisms include inflammatory cells such as alveolar
macrophages, neutrophils, monocytes, lymphocytes, and eosinophils. Alveolar
macrophages account for approximately ~95% of airspace leukocytes, with ~1 to 4%
lymphocytesand only ~1% neutrophils (160).
Alveolar macrophages represent the most important defense system both for non-
specific phagocytic defense and for antigen triggered immunity via activation of T-
lymphocytes and neutrophils recruitment (164-166).
Morphologic studies have shown that alveolar macrophages are large, mature
cells, with an increased cytoplasm/nucleus ratio, which resembles other tissue
macrophages. These cells reside within the alveolus and are often seen protruding
from the alveolar epithelial walls into the lumen of the lungs (30).
Macrophages are highly heterogeneous cells that can change their function in
response to local signals in their environment. They are commonly divided into
subpopulations based on their functional phenotype. However, rather than being
separated subpopulations, macrophages represent a spectrum of phenotypes, and they
can switch from one phenotype to another in response to signals present in the
environment.
The two commonly known sub-populations are named classically activated
macrophages, and alternatively activated macrophages. Exposure to interferon-
(IFN-) stimulates the first classic pathway of activation that yields M1
macrophages with efficient capacitiesfor phagocytosis, antigen presentation and
production of Th1 cytokines, including IL-1, IL-6, IL-12, and tumor necrosis factor-
(TNF-, that are all important for clearance of intracellular and bacterial
pathogens. Conversely, the alternatively activation take place when macrophages
57 Introduction
gather with IL-4 and IL-13, involving Th2 responses and antiinflammatory functions
(165, 166).
Interestingly, though alveolar macrophages are critical for the normal function of
the innate and adaptive immune responses during host defense, they might be also
implicated in the abnormal function of these same systems when they drive
inflammatory diseases.
As alveolar macrophages are the primary sentinel cells which sensed pathogens
and elaborated a cytokine response, neutrophils are key effector cells of the innate
immune system recruited by macrophages (164). These cells are recruited through the
pulmonary capillaries and into the air spaces, being initiated by the upregulation of
adhesion molecules on pulmonary endothelial cells (167). Intravasated neutrophils
phagocytose microbes, which are killed by reactive oxygen species, antimicrobial
proteins, and degradative enzymes. Neutrophils also produce proinflammatory
cytokines that recruit and activate other cells of the innate and adaptive immune
system. Thus, alterations in neutrophil functions predispose the lung to respiratory
infections and may exacerbate inflammation (164).
Figure 16. Ultrastructural appearance of an alveolar macrophage by electron
microscopy. Alveolar macrophage (AM); alveolar type I cell (ATI); nuclei (N). (Image
from © 2005, Angeline Warner, D. V. M., D. Sc.)
58 Introduction
3. Acute lung injury
Acute lung injury (ALI) results from a dysregulated inflammatory response, and
can progress to severe respiratory failure termed the acute respiratory distress
syndrome (ARDS).
The first description of ARDS was published in 1967, when Ashbaugh and
colleagues described patients in intensive care units with an onset of respiratory
failure characterized by hypoxemia refractory to oxygen therapy, decreased lung
compliance, and diffuse alveolar infiltrates on chest radiograph, preceded either by
severe trauma, viral infection, or acute pancreatitis (168).
Thereafter, Murray and colleagues proposed a 4-point lung-injury scoring system
based on the statement that severity of lung injury determines survival. This 4-point
score was assessed by measurements of lung function, lung compliance, and degree of
pulmonary edema (169). However, the clinical usefulness of this score was limited
because it could not be used to predict outcome in the first 24 to 72 h after the onset
of ARDS.
In 1994, the American-European Consensus Conference Committee on ARDS
proposed the currently widely accepted defining clinical criteria to distinguished ALI
and ARDS based on the extent of hypoxemia (defined by a ratio of the partial
pressure of arterial oxygen [PaO2] to the fraction of inspired oxygen [FiO2]) (Table
1). In addition, acute onset, presence of bilateral infiltrates seen on lateral chest
radiograph and a pulmonary artery wedge pressure (PAWP) <18 mmHg or no clinical
evidence of left atrial hypertension are the other defining features of ALI/ARDS (2).
59 Introduction
3.1. Epidemiology
3.1.1. Incidence
ALI/ARDS mortality rates have declined over the last 2 decades. In the 1980s,
mortality rates were approximately 60–70% (170-172). However, these rates must be
interpreted with caution, as accurate estimations were difficult to assess due to the
lack of uniform definitions and diagnosis criteria until the 1994 consensus definitions
together with the presence of etiologic variations, geographical variation and
inadequate documentation (173).
In 2003, Goss and colleagues (174) used the NIH-funded ARDS network
database to prospectively identify ALI patients from 1996–1999, estimating an
incidence of 64.2 cases per 100,000 person-years. More recently, Rubenfeld and
colleagues (175) estimated that there are 200.000 cases of ALI each year in the United
States, associated with 74.500 deaths, estimating a 39% mortality that accords with
mortality rates of 40-60% previously assessed in other studies (3).
ONSET OXYGENATION CHEST
RADIOGRAPH PAWP
ALI Acute PaO2/FiO2<300
mm Hg
Bilateral
infiltrates
<18 mmHg/ no
left atrial
hypertension
ARDS Acute PaO2/FiO2<200
mmHg
Bilateral
infiltrates
<18 mmHg/ no
left atrial
hypertension
Table 1. Definition of Acute Lung Injury (ALI) & Acute Respiratory
Distress Syndrome (ARDS) from the American-European Consensus
Conference 1994 [163].
PaO2: partial pressure of arterial oxygen; FiO2: fraction of inspired oxygen.
60 Introduction
3.1.2. Risk factors
The American-European Consensus Conference in 1994 defined several clinical
disorders capable of triggering ALI divided according to the mechanism through
which they cause lung damage (2). Thus, the first group of the disorders causes direct
injury to the lung whereas the second group induces lung damage indirectly (Table 2).
For example, pneumonia and aspiration of gastric contents belong to the most
common causes of direct ALI whereas the most common causes of indirect ALI are
sepsis and severe trauma with shock and multiple transfusions. Specifically, sepsis
has a higher mortality rate than major trauma (43 vs. 11%) whereas pneumonia and
aspiration have intermediate mortality rates (36 and 37%, respectively) (176).
Other factors that influence mortality appear to be age and race. Rubenfeld and
colleagues (175) found that mortality was significantly lower in patients 15–19 years
of age (24%) compared to patients 85 years of age or older (60%). On the other hand,
racial inequalities also occur, e.g. African-Americans and Hispanics have a higher 60-
day mortality rate (33%) compared to Caucasians (27%) (177). Finally, patients with
multiple comorbidities, chronic alcohol abuse, or chronic lung disease, have an
increased risk for ALI development (3).
DIRECT INJURY INDIRECT INJURY
Diffuse pulmonary infection (e.g.
Pneumonia)
Aspiration
Lung contusion
Near drowning
Toxic inhalation
Sepsis
Transfusion-related
Pancreatitis
Sever non-thoracic trauma
Cardiopulmonary bypass
Table 2. Clinical disorders associated with development of ALI & ARDS, as
identified by the American-European Consensus Conference Committee 1994
(2).
61 Introduction
3.1.3. Outcomes
Patients who survive ALI have been shown to have a reduced health-related
quality of life (178) and persistent functional limitation largely as a result of muscle
wasting and weakness. In fact, mild lung function alterations such as gas-exchange
deficit with exercise and residual impairment of pulmonary mechanics persist after
the resolution of the syndrome, but these abnormalities seem to be asymptomatics
(179) and in most patients, pulmonary function returns to normal within 6-12 months
(180).
3.2. Pathogenesis
Acute lung injury is a disorder of acute inflammation that causes disruption of the
lung endothelial and epithelial barriers. Cellular characteristics of ALI include loss of
alveolar–capillary membrane integrity, excessive transepithelial neutrophil migration,
and release of proinflammatory, cytotoxic mediators (173).
In humans, the intrapulmonary inflammatory response begins before the onset of
clinically defined ALI and is most intense in the first 3 days after the onset of
ALI/ARDS (181, 182). This acute phase is characterized by the leakage of protein-
rich edema fluid and inflammatory cells into the alveolar space together with the
formation of characteristic hyaline membranes. This ALI stage, also named exudative
phase, rises as a consequence of both endothelial and epithelial cell injury with
increased permeability of the alveolar-capillary barrier (3, 183, 184) (Figure 17).
The subsequent histopathological stage of ALI (after ~1-2 weeks), known as the
proliferative phase, is characterized by the proliferation of ATII cells along alveolar
septa and the onset of epithelial regeneration (184). Under normal conditions, the
denuded basement membrane is re-epithelialised with restoration of normal alveolar
architecture and epithelial fluid transport capacity and rapid re-absorption of alveolar
edema. However, in some patients alveolar edema persists, mesenchymal cells fill the
alveolar spaces leading to a fibrotic stage (3).
3.2.1. Endothelial and epithelial injury
Disruption of the alveolar-capillary barrier is a well-established mechanism
responsible for the influx of protein-rich edema fluid into the air spaces during the
62 Introduction
initial phase of ALI (183). Therefore, the alteration of any of the components
comprising the alveolar-capillary barrier may lead to the development of pulmonary
edema that entails physiological events including hypoxemia and reduced lung
compliance in ALI/ARDS patients (185).
During ALI, microvascular endothelium is injured by proinflammatory cytokines,
activated immune cells and reactive species leading to an increased of capillary
permeability. This alteration allows the efflux of protein-rich fluid into the
interstitium, ultimately crossing the epithelial barrier into the distal airspaces of the
lung (183). Several studies have documented increased release of von Willebrand
factor (186-188) and upregulation of intracellular adhesion molecule-1 (ICAM-1)
(189, 190) following endothelial injury. Also, endothelial damage contributes to
leukocyte recruitment, coagulation disorders and vascular leakage.
On the other hand, the loss of epithelial integrity contributes importantly to
edema formation for several reasons. Normally, ATI and ATII cells form tight
junctions with each other, selectively regulating the epithelial barrier. Their alteration
leads to disruption of normal fluid transport via down-regulated epithelial Na
channels and Na+/K
+ATPase pumps, impairing the resolution of alveolar flooding (3,
183).
As a result, increased permeability of this membrane during the acute phase of
ALI leads to the influx of protein-rich edema fluid into alveolar space. Also, epithelial
injury alters PS production by ATII cells (191), predisposes the lung to fibrosis during
the later phases of ALI (192) and what is more, it allows the development of sepsis in
those patients with pneumonia due to the entrance of bacteria into circulation (193).
3.2.2. Inflammation
Aberrant activation of the immune system (i.e., increase in neutrophils and
cytokines) contributes to pulmonary edema in ALI and ARDS (194). Normally, >90%
of the alveolar cells in the alveolar fluid are alveolar macrophages and >2% are
neutrophils. However, in ALI this ratio is reversed and neutrophils comprised >90%
of the alveolar fluid cells (195).
Macrophages contribute to ALI by regulating inflammatory and immune
responses through the release of several mediators including cytokines, chemokines,
metalloproteases or reactive oxygen species (ROS) (195). As well, endothelial and
63 Introduction
ATII cells can also produce several cytokines and chemokines under numerousALI
stimuli (196-199). Furthermore, some of the ALI mediators can up-regulate various
surface molecules on the endothelial and epithelial surface allowing leukocytes,
primary neutrophils, to adhere and migrate across the alveolar-capillary barrier (200-
202).
In fact, a marked neutrophil accumulation is characteristic of the acute phase of
ALI, suggesting that these cells play an important role in the pathogenesis of lung
injury as they are considered primary perpetrators of inflammation (203-205).
Excessive and/or prolonged activation of neutrophils contribute to basement
membrane destruction and increased permeability of the alveolar–capillary barrier
(205, 206). Specifically, elastase, a widely studied neutrophil mediator, seems to
degrade epithelial junctional proteins and possess pro-apoptotic and direct cytotoxic
effects on the epithelium (207, 208). Furthermore, ARDS patients with increased
levels of granulocyte-colony stimulating factor (a neutrophil anti-apoptotic factor) in
the lung lining fluid, have poorer outcomes (209).
On the other hand, a complex balance of pro- and anti-inflammatory cytokines
appears to initiate and regulate the inflammatory response in ALI (3, 182). Cytokines
are low-molecular weight soluble proteins that transmit signals between cellsinvolved
in the inflammatory response (210).
IL-1β and TNF-α are unrelated early response cytokines as they are found in the
early stages of ALI and are able to initiate further inflammatory responses. Several
human studies determined that both cytokines play a role in mediate ALI as well as
maintaining the inflammatory response (211). Besides, they are able to induce
additional cytokine production including IL-6 and IL-8 (212). IL-6 is a pleiotropic
cytokine with multiple functions such as stimulation of acute phase proteins, T-cells
activation or even inhibits IL-1β and TNF-α production (213). IL-8 belongs to the
CXC chemokine family that has significant neutrophilchemotactic activity (214).
In patients with ALI/ARDS, those proinflammatory cytokines are persistently
elevated in plasma and are strongly predicative of mortality (215-217). As well, IL-
1β, TNF-α and IL-8 are elevated in the alveolar fluid of ARDS patients (211, 215,
218). Thus, systemic and local production of proinflammatory cytokines initiates and
amplifies the inflammatory response and the subsequent injury in ALI and ARDS.
64 Introduction
However, the presence of several specific inhibitors of proinflammatory
cytokines including IL-1-receptor antagonist (IL-1ra), soluble TNF receptor (sTNF-R)
and auto-antibodies against IL-8 and non-specific antiinflammatory cytokines like IL-
10 and IL-11 has been described to modulate inflammatory lung injury. Nonetheless,
their low presence in the alveolar fluid of ARDS patients is associated with increased
mortality rates (3, 182). Therefore, a balance between pro- and antiinflammatory
mediators may lead to a solving proliferative phase or a proliferative phase leading to
fibrotic processes.
Figure 17. Pathophysiology of the acute phase of acute lung injury. Left side
represents a normal alveolus; Right side represents an injured alveolus characterized by an
edematous and an inflammatory state in the acute phase of lung injury. Alveolar Type I
cell (ATI); Alveolar Type II cell (ATII); Interleukin (IL)-1-6-8-10; TNF-Tumoral
necrosis factor ROS: Reactive Oxygen Species.
65 Introduction
3.3. Treatment
Currently, treatment of ALI is based in both ventilatory and non-ventilatory
strategies. However, for many years, treatment of ALI was limited to the supportive
treatment of organ failure and treatment of the underlying cause of lung injury.
Improvements in this supportive treatment, rather than the success of a particular
therapeutic intervention, are thought to account for the recently observed decline in
mortality from (60-70% to ~30-40% (3)).
The best evidence for the value of a lung protective strategy in patients with ALI
is a study by the ARDS Network (ARDSNet) comparing conventional mechanical
ventilation with a lung protective strategy of ventilation. This study reported a 22%
reduction in mortality in patients ventilated using protective ventilation together with
more ventilator free and non-pulmonary organ failure-free days (219). Moreover,
clinical risk factors including sepsis, aspiration, pneumonia, and trauma did not affect
the efficacy of the protective strategy of ventilation (176).
Despite significant advances in the understanding of the pathogenesis of ALI,
specific pharmacological interventions, including surfactant therapy, inhaled nitric
oxide, glucocorticoids and other antiinflammatory agents, have shown little benefit al
phase III trials (173, 220).
There has been considerable preclinical data supporting the potential value of -2
agonist therapy for the treatment of ALI as it has been suggested that they able to
decrease inflammation and upregulate alveolar salt and water transport, hastening the
resolution of alveolar edema (221-223). However, only a randomized trial in the UK
recently demonstrated that intravenous salbutamol significantly lowered extravascular
lung water (224).
Currently lines of investigation are focused on the potencial benefits of enteral
feeding (225), the use of statins, which are normally used for the prevention or
treatment of cardiovascular diseases and also have significant antiinflammatory,
immunomodulatory, and antioxidant effects (226-228), and treatment with bone
marrow-derived mesenchymal stem cells (MSCs) as they possess the ability to
differentiate into many types of cells and also are able to secrete paracrine factors that
reduce the severity of ALI (e.g. growth factors, factors that regulate barrier
permeability and antiinflammatory cytokines) (229, 230).
66 Introduction
3.4. Animal models
Modeling human disease in animals has contributed significantly to our
understanding of lung physiology in health and in disease (231).
As human studies provide important descriptive information about the onset and
evolution of the physiological and inflammatory changes leading to formulate
hypothesis about the mechanisms of injury, animal models provide a bridge between
patients and the laboratory bench to test these hypothesis (232).
The hypotheses formulated in human studies are difficult to test in
humansbecause of the many clinical variables that are difficult to control in critically
ill patients. Therefore, these hypotheses can be tested directly in animal models
together with the results of in vitro studies in order to assess their relevance in intact
living systems. Without animal models there would be no way to test clinical
hypotheses generated in patients using intact biological systems, and there would be
no way to validate the importance of fundamental laboratory findings without going
directly to human experimentation (232).
Ideally, animal models of ALI should reproduce one or more features of human
ALI, including rapid onset (hours) after an inciting stimulus, evidence of pulmonary
physiological dysfunction (e.g., abnormalities of gas exchange, decreased lung
compliance), histological evidence of injury to the lung parenchyma (endothelium,
interstitium, epithelium), and evidence of increased permeability of the alveolar-
capillary membrane. As well, the evolution of the injury and repair should also be
reproduced, as the responses of the lungs to injury change with time. Ideally, the
injury should evolve over time if the animals are supported for prolonged periods or
even if specific studies focus on a narrow time frame (4, 232). However, no single
animal model reproduces all of the characteristics of ALI/ARDS in humans, and most
of the existing animal models are relevant for only limited aspects of human
ALI/ARDS (4, 232).
There are many anatomical and physiological differences between animals and
humans that influence the response of the lung to an acute injurious stimulus and
affect the evaluation of lung injury (233):
(I) Respiratory rate: in humans an adult respiratory rate of ~12–16 bpm whereas in
mice rise to ~250–300 bpm, rendering absolute respiratory rate inadequate as a
parameter of ALI in mice (4, 5).
67 Introduction
(II) Gross and microscopic anatomy: mice and rats have different lobar anatomy,
fewer branches of the conducting airways proximal to the terminal bronchioles.
As well, both, alveoli and thickness of the blood–gas barrier are smaller in the
lungs of mice and rats compared with humans.
(III) Inflammation: rodents have fewer circulating neutrophils (~10–25%) than
humans (~50–70%) and do not express defensins. The neutrophil collection of
CXC chemokines differs between rodents and humans (keratinocyte-derived
chemokine KC [CXCL1] and macrophage inflammatory protein [MIP-2] in
rodents and IL-8 in humans) (232, 234).
(IV) ALI settings: murine lungs rarely demonstrate hyaline membranes under
enhance permeability situations.
(V) ALI development: in humans, ALI is developed in patients affected by the
mechanisms involved in a primary illness (e.g., sepsis) and/or therapeutic
modalities used for supportive care (e.g., mechanical ventilation) whereas
animal studies frequently use young mice with no comorbidities (232).
For all of these reasons, the responses of animal and human lungs to an injurious
stimulus cannot be expected to be identical or perhaps even similar.
To address this problem in 2010, an Official Committee was established in
American Thoracic Society (ATS) Workshop (4) to determine the main features that
characterize ALI in animal models and to identify the most relevant methods to assess
these features. They concluded that the main features of experimental ALI include
histological evidence of tissue injury, alteration of the alveolar capillary barrier,
presence of an inflammatory response, and evidence of physiological dysfunction;
they recommended that, to determine if ALI has occurred, at least three of these four
main features of ALI should be present. However, the Committee emphasized that the
list of ALI features is intended as a guide for investigators in which they might choose
according to the experimental questions addressed and the specific aspects of each
experimental design chosen.
Commonly used animal models are based on clinical disorders that are associated
with ALI/ARDS in humans. Investigators have tried to reproduce each of these risk
factors in a variety of animals, and the frequency with which each model has been
reported is shown in Table 3 (232). Each model has their own characteristics,
advantages and similarities with ALI human models. However, animal models of
68 Introduction
ventilator-induced lung injury are the more frequently studied because is the only
model that has affected clinical practice and improved survival in humans (232).
4. Ventilator-induced lung injury
Mechanical ventilation (MV) is routinely used for decades to provide respiratory
support in critically ill patients. However, its safety for the treatment of ARDS
patients has been a matter of concern ever since its introduction into medical practice
(235). Yet already in 1974, Webb and Tierney demonstrated for the first time that MV
could generate lung lesions in intact animals (236). Since then, several experimental
and clinical studies have been performed to clarify the potential drawbacks of MV
and its subsequent outcomes according to the strategy applied.
Currently, we should take into account two different concepts related to MV
alterations, ventilator-associated lung injury (VALI) and ventilator-induced lung
injury (VILI). VALI is referred to the additional injury imposed on a previously
injured lung by MV in either clinical settings or in experimental studies (also termed
as two-hit experimental models (237)). Conversely, the term VILI is regarded as a
sole method to generate lung injury, which is the direct application of an injurious
ANIMAL MODELS OF ACUTE LUNG INJURY %
Mechanical Ventilation
LPS
Live bacteria
Hyperoxia
Bleomycin
Oleic acid
Cecal ligation and puncture
Acid Aspiration
30
19
16
12
10
5
4
3
Table 3. Percentage of the different animal models used to
study Acute Lung Injury.
Table modified from reference (226).
69 Introduction
MV strategy (238). Here, we are going to focus mainly on VILI and its pathogenesis.
4.1. Determinants of VILI
4.1.1. Mechanical determinants
Barotrauma vs. Volutrauma
The term barotrauma is used to describe the lung damage attributable to MV
with high peak pressures (239). However, a study performed by Dreyfuss and co-
workers (240) suggested that lung distension was more important to cause lung injury
than airway pressure per se, coining the term volutrauma. In order to elucidate this,
they ventilated rats with identical peak pressures using high or low tidal volumes
(VT). As a result, they observed that rats subjected to high VT-high pressure
ventilation developed pulmonary edema whereas those subjected to low VT-high
pressure ventilation did not. Subsequently, other groups confirmed and replicated
these findings in other experimental models (235, 241, 242).
Therefore, the important fact is trans-pulmonary pressure (i.e. the pressure across
the lung: airway pressure [alveolar pressure] – pleural pressure) and not the airway
pressure itself (243).
Atelectrauma
It is important to highlight that ARDS patients had their lungs heterogeneously
injured leading to their alveoli to pass thought one of three following conditions: (I)
fluid-filled or collapsed, and thus closed and not inflated; (II) collapsed or filled with
fluid at end-exhalation, but opened and air-filled at end-inspiration; or (III) expanded
and aerated throughout the respiratory cycle (244).
As the collapse of an alveolus causes shear stress not only on its own walls but
also on those of adjacent alveoli, heterogeneously MV lungs are susceptible to cyclic
damage by shear stress resulting from repetitive alveolar collapse and overdistension
(or recruitment-derecruitment), termed atelectrauma (239).
Thus, the application of positive end-expiratory pressure (PEEP) effectively
opens the distal airways, maintaining recruitment throughout the ventilatory cycle
(243).
70 Introduction
The application of PEEP during VILI development has been associated with a
preservation of the integrity of the alveolar epithelium besides few alterations
including endothelial blebbing and interstitial edema (240). However, the influence of
PEEP in VILI mustbe studied with caution according to the VT used.
Protective ventilatory strategies: Low VT and PEEP
The bases of lung protective strategies reside in: (I) prevention alveolar
overdistention by limiting VT/ airway pressures; and (II) to maintain alveolar
recruitment throughout the respiratory cycle through the addition of PEEP.
Webb and Tierney (236) showed that edema was lessened by PEEP application
during MV with high peak airway pressures and they attributed the beneficial effect to
the preservation of PS activity.
Later studies demonstrated that VT reduction, maintaining the same level of
PEEP, significantly reduced both endothelial and epithelial injury and this was
associated with lower histological lung injury severity scores (245). Furthermore,
clinical trials reported significant decreases in the levels of both pulmonaryand
systemic inflammatory mediators in patients ventilated using lung protective
strategies (246). Moreover, the ARDSnet trial determined a reduction of 22% in the
mortality rates of those patients MV with lower VT (6 ml/kg) compared to those
ventilated with traditional VT (12 ml/kg) (219). Besides, the protective effect of PEEP
was highlighted by Amato and colleagues, which demonstrated that the use of high
levels of PEEP to alveolar recruitment resulted in improved 28 day-mortality (247).
4.1.2. Biotrauma
Barotrauma/Volutrauma and atelectrauma has been considered the principal
causes of VILI until the biotrauma hypothesis emerged (248).
Biotrauma relies on the hypothesis that lung tissue stretching might result in lung
injury through the release of inflammatory mediators and leukocyte recruitment (249,
250). This inflammatory reaction may not be exclusively of lungs, it may also involve
systemic circulation, altering distal end-organs and therefore providing an explanation
to the observation that most patients with ARDS die from multiple organ failure
rather than hypoxemia (7, 251).
71 Introduction
This hypothesis is supported by several clinical trials that observed that ARDS
patients ventilated with a protective strategies exhibited lower bronchoalveolarlavage
fluid and/or plasma concentrations of inflammatory mediators than patients ventilated
with control strategies (252-254). Intriguingly, one of these studies observed an
increased of most of antiinflammatory cytokines rather than proinflammatory (254),
emphasizing that it remains unclear whether mechanical ventilation affects the
balance of cytokines toward pro- or anti-inflammation (255).
Accordingly, experimental studies also suggested that MVcould influence the
proinflammatory/antiinflammatory balance in the lungs. Specifically, Tremblay et al.
(250) showed in unperfused rat lungs that high VT ventilation with zero PEEP
resulted in a dramatic increased of proinflammatory cytokines levels (TNF-, IL-1
and macrophage inflammatory protein [MIP-2]) in lung lavage compared with
controls. However, using the same model of unperfused rat lungs, others found only
slightly higher IL-1 and MIP-2 bronchoalveolar lavage fluid concentration in
injuriously MV rats compared with control ones, together with no changes in TNF-
lung lavage levels among groups (256, 257). The authors concluded that injurious
MV strategies do not necessarily result in primary production of proinflammatory
cytokines in the lungs (257).
As a result, the concepts barotrauma/volutrauma, atelectrauma and biotrauma
are currently considered as interrelated and not exclusive in the induction of stress
failure since the mechanical determinants seem to induce biotrauma. Thus, ventilation
with high VT or pressures can cause release of proinflammatory mediators by a
number of different mechanisms, all of which appear to be clinically relevant (248):
Injurious MV can cause stress failure of the plasma membrane and epithelial and
endothelial barriersleading tonecrosisand subsequent liberation of inflammatory
mediators that will stimulate other intact cells to produce such mediators.
Stress failure of the barriers causes loss of compartmentalization with the
consequent spreading of inflammatory mediators throughout the body.
MV with increasing positive pressures raises the pressure in the pulmonary
circulation and thus vascular shear stress, stimulating endothelial cells.
Less injurious ventilation strategies that do not cause tissue destruction can elicit
release of mediators by more specific mechanisms, presumably through
activation of stretch-activated signaling cascades, termed as
72 Introduction
mechanotransduction. As the sensing mechanism of these physical forces and
the translation into cellular signals is largely unknown, several experimental
studies in vitro and in vivo observed that mechanical stretch induce distinct
patterns of gene expression including genes involved in immunity and
inflammation, stress response, metabolism and transcription processes (258, 259).
4.2. Pathogenesis
4.2.1. Microscopic pathology
Animal lungs injured by MV present a pattern of atelectasis, severe congestion
and enlargement due to edema, which is associated with severe endothelial and
epithelial abnormalities, the structural counterpart of permeability alterations (235,
236, 240, 260, 261).
Tsuno and coworkers (262) microscopic examination revealed that baby pig
lung‟s subjected to high-pressure MV during 22h presented severe diffuse alveolar
damage,with hyaline membranes, alveolar hemorrhage, and neutrophil infiltration.
Also, small animals experimental studies depicted that under high peak pressures
there were wide spread alterations of endothelial and epithelial barriers observed by
electron microscopy (240, 260, 261, 263) together with edema presence. Specifically,
they observed ATI cells discontinuities with some areas completely destructed
leaving a denuded basement membrane, hyaline membranes filling the alveolar spaces
and endothelial cells alterations including their detachment from their basement
membrane resulting in the formation of intracapillary blebs or even endothelial cell
breaks, allowing direct contact between neutrophils and the basement membrane
(240, 261).
However, there is an obvious relationship between the duration and severity of
the mechanical injury and the overall appearance of the lung. Also, the animal model
used entails different outcomes. Thus, edema is developed so rapidly in small animals
that the lack of time prevents neutrophil infiltration. In contrast, larger animals need
several hours to produce patent edema, time enough for activation, adherence, and
significant migration of neutrophils into airspaces (262, 264).
73 Introduction
4.2.2. Alveolar edema
As previously described, VILI may produce breaks in the alveolar-capillary
barrier leading to alveolar hemorrhage (240, 260, 261). Thus, this disruption can be
also promoted by non-uniform mechanical lung inflation altering microvascular
pressure, termed shear stress (235). However, alveolar edema presence could be
alsoproduced due to alterations in the alveolar-capillary barrier permeability.
Experimental studies have implicated epithelial and endothelial permeability
changes in the presence of high content-protein edema in the alveolar space (243).
Increase of epithelial permeability to small hydrophilic solutes occurs as lung
volume increases, being this a physiologic phenomenon. The clearance of aerosolized
99mTc-DTPA increased when the functional residual capacity was increased by
applying PEEP during MV (265), or during spontaneous ventilation (266) in sheep.
The same observation has been made in humans (267, 268).
However, only major increasesin lung volume alter epithelial permeability to
largemolecules during static inflation (235). Hence, some studies depicted that
increased static inflation of fluid filled lung lobes in sheep led to the passage of larger
solutes across the epithelium, a finding observed inother models (269, 270).
Moreover, the redistribution of 125
I-labelled albumin intothe extravascular space in
MV rats demonstrated the presence of increased microvascular permeability (261).
Furthermore, similar experimental studies in other species confirmed the alteration of
endothelial permeability to solutes of both small and large molecular weight (271,
272).
In contrast to the clear evidence for increased permeability, relatively little is
known about the contribution of hydrostatic pressures to the development of
pulmonary edema in MV (243).
4.2.3. Inflammation
The role of the innate immune response and inflammation in the pathogenesis of
VILI has been widely studied in recent years. Researchers have used a variety of
experimental models to determine the effects of MV or mechanical strain on the
expression of biological markers of inflammation or injury, including animal models,
74 Introduction
ex vivo lung preparations and isolatedalveolar epithelial cells (238).
The role of inflammatory cells
Although many resident lung cells can produce inflammatory mediators, alveolar
macrophages have a large capacity for cytokine and chemokine production, as well as
nitric oxide and reactive nitrogen species elaboration (273). Specifically, several
studies depicted a possible role of alveolar macrophages in the initial pathogenesis of
VILI.
Mechanical deformation of human alveolar macrophages in vitro, has been
shown to increase the expression of IL-8 and matrix-metalloproteinase-9 (MMP-9)
together with an increase in nuclear translocation of the transcription factor nuclear
factor kappa-B (NFκB) after 30 min of cyclic strain (274).
Frank and colleagues work also suggests that macrophage activation is an early
and critical event in the initiation of VILI. They demonstrated that addition of
bronchoalveolar lavage from rats exposed to injurious MV during 20 minutes induced
the activation of naïve primary alveolar macrophages in culture. Furthermore, they
observed that macrophage depletion decreased ventilator-induced endothelial and
epithelial injury (273), supported by Eyal and co-workers (275).
In addition to macrophages, neutrophils have been un-equivocally implicated in
the pathogenesis of ALI and ARDS (276) and seem to be the major effector cells in
the generation of the tissue injury characteristic of VILI (277).
One of the first studies proposing that MV could lead to an inflammatory
response used a model of neutrophil depletion by nitrogen mustard. Kawano et al.
(264) demonstrated that the neutrophil-depleted animals had markedly improved
oxygenation and decreased pathologic evidence of injury after MV versus a control
group treated with the lavage and ventilatory protocol alone.
Further evidence for the central role of the neutrophil in VILI has been provided
by the work of Zhang and colleagues. In this study, alveolar lavage fluid obtained
from ventilated patients with ARDS was incubated with neutrophils from normal
volunteers. As a result, markers of neutrophil activation were significantly higher in
those ventilated conventionally compared to those ventilated with a lung protective
strategy (278). Interestingly, alveolar recruitment of neutrophils by instilling a
chemmoatractant does not result in lung injury (279), indicating that other mediator
75 Introduction
possibly cytokines, are necessary to activate leukocytes.
The role of inflammatory mediators
It is widely accepted that increased production of cytokines in the lung plays a
key role in VILI. To examine the mechanisms of cytokine generation during MV, in
vitro, ex vivo and in vivo models have been conducted (256).
Upon stretch, cultured alveolar cells produce inflammatory mediators such as
TNF- IL-1, IL-6, IL-8, IL-10 (274, 280). There are several reports of MV increased
cytokines and chemokines in whole-animal models. Specifically, MV with high VT
results in increased levels of the proinflammatory cytokines in lavage fluid, including
TNF-and MIP-2 (281-283). However, other models under injurious MV detected no
significant changes of TNF- in the alveolar lavage though other proinflammatory
levels were augmented (284).
Also, the use of isolated lung models allowed determining changes in the levels
of many inflammatory mediators in VILI. The work of Tremblay and co-workers
(250) previously mentioned, demonstrated that high VT, zero PEEP MV induced a
greater increase in airspace of TNF- IL-1, IL-6, IL-10, MIP-2, and interferon-
than low VT with or without PEEP application. Furthermore, similar to the study of
Tremblay et al (250), Veldhuizen and colleagues (285) found that in isolated mouse
lungs, ventilation with a tidal volume of 20 mL/kg without PEEP resulted in
significant increased in BAL levels of TNF- and IL-6.
On the other hand, clinical studies seem to support the concept that injurious MV
promotes a pulmonary inflammatory response and cytokine decompartmentalisation.
Ranieri and colleagues (246) reported significant decreases in bronchoalveolar fluid
and plasma concentrations of many inflammatory mediators (TNF-, IL-6 and IL-8)
in patients MV with a lung protective strategy. Moreover, the ARDSnet trial depicted
that patients ventilated with a lung protective strategy had a greater decrease in levels
of plasma IL-6 (219).
Despite the fact that low VT MV ameliorates the inflammatory response, some
studies confirmed that subjects subjected to MV may develop a proinflammatory state
(286, 287). In fact, it is not yet established the ventilatory strategy that is the most
effective in limiting inflammation.
Other mediators implicated in VILI include coagulation factors, such as
76 Introduction
plasminogen activator inhibitor-1, hormones, such as angiotensin-II and lipid derived
mediators, such as cyclooxygenase and lipoxygenase (288). As well, some studies
observed the implication of metalloproteases in the early stages of VILI (289) and
ROS production in response to elevated mechanical stress (290-292).
4.2.4. Pulmonary surfactant alterations
PS plays a role in VILI in two related ways. Firstly, PS dysfunction or deficiency
seems to amplify the injurious effects of MV and, secondly, MV itself can impair PS
function thereby exacerbating the existing damage (243).
It is widely accepted that mechanical stretch of ATII cells in vitro stimulates
surfactant release (293). As well some animal models observed that total PS increased
(294, 295). However, injurious MV strategies of high VT and zero PEEP lead to
alterations in functional PS and a decreased LA/SA ratio (285, 294, 296-298).
PS biophysical function impairment may contribute to VILI in several ways
(243): (I) Alveoli and airways tend to collapse with generation of shear stress as they
are reopened; (II) The irregular expansion of lung units increases regional stress
forces through interdependence; (III) The transvascular filtration pressure is
increased, promoting edema formation (299).
In addition, PS system is thought to have important immunoregulatory functions
(148), which may become impaired through MV.
Therefore, improving the presence of an increased pool of functioning PS might
lessen lung injury by MV as some studies suggested that surfactant therapy
contributes to reduce mortality in the neonatal respiratory distress syndrome and may
decrease lung injury (300).
4.2.5. Consequences following VILI
Abnormal or dysregulated repair processes are associated with increased
morbidity and mortality following ALI/ARDS (301). However, the factors leading
either to the fibrotic phase or resolution are incompletely understood. Nevertheless,
some studies suggest that some transcriptional responses in ALI genes involved in
inflammation and repair are differentially expressed simultaneously very early in the
77 Introduction
course of injury (302), and many mediators are common to both processes. This is
further supported by evidence that patients with well known chronic fibrotic lung
disorders have persistently elevated levels of ALI related cytokines and chemokines
in alveolar lavage samples (303, 304).
Regarding to VILI, few studies have been conducted in order to characterize the
potential mechanisms that occurs during resolution and repair following injurious MV
(305-307). These studies observed that MV induced severe injury in the lungs
characterized by histologic injury and edema, but they were able to repair
spontaneously in the absence of further ventilation. Furthermore, Curley and co-
workers (306) studied the evolution of several inflammatory and fibroproliferative
markers throughout two-weeks, detecting that proinflammatory cytokines returned to
baseline within 24h, while anti-inflammatory remained increased for48 h. Moreover,
VILI generated a marked but transient fibroproliferative response, which restored
normal lung architecture represented as absence of evidence of fibrosis at 7 and 14
days.
Also, González-López et al (308) studied the mechanisms of repair after VILI
using a model of injurious MV followed by a protective MV strategy during 4 hours.
They also observed that surviving animals were recovered from the injury
characterized by increased cell proliferation, lower levelsof collagen, and higher
levels of MIP-2 and MMP-2.
Therefore, these data suggest that VILI may be potentially reversible, and that the
repair process depends on both an adequate inflammatory response and extracellular
matrix remodeling. However, further investigation must be done in order to elucidate
the precise roles of the factors involved in the resolution and repair processes
following VILI.
78 Introduction
Objectives 79
Objectives
Objectives 80
Objectives 81
The lung is a delicate organ that can develop significant dysfunction in response to
minor injury. The pathophysiology of acute respiratory distress syndrome (ARDS) or
the less severe condition known as acute lung injury (ALI) (2) is currently thought to
begin with an inflammatory response induced by extrapulmonary injury (sepsis, severe
trauma, acute pancretitis, etc.) or direct pulmonary injury (pneumonia, aspiration of
gastric contents, pulmonary contusion, etc.) (3). The inflammatory response increases
alveolar epithelial and pulmonary vascular endothelial permeability, causing alveolar
filling (3, 4). The alteration of the pulmonary surfactant system complicates the clinical
picture (5).
Lung surfactant serves to stabilize the alveoli and distal airways at low lung
volumes (1), and deficit or alteration of this macromolecular complex strengthens
intraalveolar edema, impairs lung compliance, andresults in ventilation-perfusion
mismatch (including shunt flow due to altered gas flow distribution) and hypoxemia (1,
5, 6). Critical hypoxemia results in the need for mechanical ventilation, thereby
providing the context in which ventilator-induced lung injury (VILI) can develop (7). It
is thought that VILI is generated as a result of volutrauma (intensified tissue tensions at
the junctions of closed and open alveolar units when subjected to high alveolar
pressure) and/or atelectrauma (caused from the cyclical airspaceopening and closing)
(7). These stresses might further stimulate the inflammatory response (termed
biotrauma) resulting in progressive lunginjury and systemic inflammation (7).
The current respiratory support in ALI or ARDS consists of low tidal volume (to
reduce volutrauma) and appropriate positive end-expiratory pressure (PEEP) and/or
FiO2/PEEP ratio (to reduce atectrauma) (8). The application of PEEP is thought to be
useful in counteracting increased surface tension (thereby reversing the resulting
atelectasis). PEEP increases end-expiratory airspace pressure, but since airspace
opening pressures can vary markedly between and within patients, applying PEEP to
reverse or limit dorsal-caudal atelectasis will almost always come at the expense of
over-distending ventral lung regions and other areas having lower opening pressures
(9).
Given the importance of ventilatory management for acute respiratory syndrome
(ARDS or ALI) (7, 8), investigators have started to explore the effects of ventilation in
healthy lungs. Animal models exposed to conventional and injury ventilator strategies
Objectives 82
have being used to understand the mechanisms of lung injury induced by mechanical
ventilation.
In this thesis, healthy rats have been exposed to two different ventilator strategies
(10):
Injurious high-stretch ventilation (HV) with high tidal volumes (VT = 25 ml/kg)
and without PEEP application (ZEEP = 0 PEEP).
Conventional low-stretch ventilation (LV) with moderated tidal volume (VT = 9
ml/kg) and application of positive end-expiratory pressure (PEEP=5 cm H2O and
FiO2/PEEP ratio of 0.3/5).
The main objective of this thesis was to study morphological and functional
changes in the lungs after exposition to injurious or conventional mechanical ventilation
and to identify the relationship among high-stretch ventilation, inflammation, edema,
and surfactant dysfunction to understand the mechanisms involved in ventilator-induced
lung injury (VILI). Two important questions, currently under debate (9), will be
answered in this study: whether changes in surfactant composition and in surface
tension precede the onset of VILI, and whether VILI occurs only in animal models
when lung surfactant is inactivated.
The thesis is composed of three chapters which evaluate:
1. Lung injury after high-stretch ventilation with a complete analysis of the
composition, structure, and functional activity of lung surfactant as well as
the causes of its inactivation after high-stretch ventilation (Chapter 1).
2. Factors involved in the resistance to ventilator-induced lung injury, since
identification of such factors may help to develop prophylactic therapies or
early interventions, prior to exposition to mechanical ventilation (Chapter 2).
3. Consequences of prolonged conventional low-stretch ventilation, with or
without a previous short exposition to injurious high-stretch ventilation. This
would allow determination of whether inflammation in the lung was directly
related to the duration of conventional low-stretch ventilation (with
FiO2/PEEP ratio of 0.3/5) and whether prolonged conventional low-stretch
ventilation has beneficial or damaging effects in surviving rats exposed to
injurious high-stretch ventilation.
Material and Methods 83
Materials
and
Methods
Material and Methods 84
Material and Methods 85
1. Animals and experimental model.
Male Sprague-Dawley (SD) rats (Harlan Iberica, Spain), weighing 325-375 g were
acclimated to day/night cycles of 12 hours and fed with purina fodder (Nestlé S.A.
Vevey, Switzerland). The animals were anesthetized with ketamine (90 mg/kg) and
diazepan (5 mg/kg) by intaperitoneal route and the anesthesia was maintained during the
intervention by a continuous perfusion of ketamine (50mg/kg/h) and midazolam
(8mg/kg/h) through the femoral vein (infusion rate 10 mL/kg/h). The administration of
these drugs was made under sterile conditions.
Once anesthetized, a surgical tracheotomy was performed and a 14-gaugecannula
was secured in place and connected to a mechanical ventilator (Babylog 8000 Plus
Dräger, Germany). In addition, a 20-gauche catheter was inserted into the left carotid
artery for monitoring arterial blood pressure (Hewlett Packard, Model 66S, Geneva,
Switzerland). The surgical process was performed under sterility conditions. Body
temperature was maintained constant during the experimental procedure using a self-
regulated heat source (Challomer Ltd. Marketing, England).
Experiments were carried out following the Principles of Laboratory Animal Care
(EU 609/86 CEE, Real Decreto 1201/05 BOE 252, Spain) and the guidelines for the
care and use of experimental animals of University Hospital of Getafe (UHG). UHG
Institutional Review Board approved the protocol.
We established two mechanical ventilation strategies according to often settings
applied in clinic and experimental studies (10):
Low-stretch group, ventilated with conventional parameters: Tidal Volume [VT] = 9
ml/kg, positive end-expiratory pressure [PEEP] 5 cmH2O.
High-stretch group, ventilated with injurious parameters: VT = 25 mL/kg, zero
PEEP.
In both groups, respiratory rate was 70 bpm, inspiratory time 0.35 sec., expiratory
time 0.56 sec. and FiO2 0.35.
The animals were ventilated for an equilibration period of 30 min using the low
VT ventilation parameters. Then, the assigned ventilator strategy was administered
randomly starting at t=0 min. Dead-space ventilation (the volume of air inhaled that
does not take part in the gas exchange) was increased in animals ventilated with high VT
Material and Methods 86
(by increasing the length of the ventilatory circuit) to attain comparable values of
PaCO2 (30-40 mmHg) during the ventilation period. The animals were ventilated with
the parameters assigned during the time established in each experimental design
(detailed in each chapter).
2. Registration of hemodynamic and ventilatory parameters.
At the beginning and end of each ventilator strategy (according to the experimental
design) were registered the following parameters: mean arterial pressure (MAP) and
mechanical ventilator parameters including peak inspiratory pressure (PIP), peak airway
pressure (PAW) and dynamic respiratory system compliance (CRS).
3. Biological sampling.
At the end of the ventilatory period animals were sacrificed by exsanguination and
subsequently we proceed to sampling (Figure 1).
Figure 1: Sampling diagram.
Material and Methods 87
Plasma: Blood samples were drawn at end times (according to the experimental
protocol) to determine arterial blood gases and perform biochemical analysis.Also, 2 ml
of blood were centrifuged at 3500 rpm during 10 min at 4ºC and the resulting plasma
was store at -80ºC until its utilization for damage markers determination (Figure 2).
Cell-free bronchoalveolar lavage: bronchoalveolar lavage was performed instilling 4
times 10 ml of saline (NaCl 0.9%) at 4ºC. The bronchoalveolar lavage acquired was
centrifuged at 400g for 10 min at 4ºC to obtain the pellet of alveolar fluid cells. Total
bronchoalveolar lavage cell-free (BAL) volume was recorded and stored at -80ºC in
order to isolate pulmonary surfactant (PS). An aliquot was separated to perform
biochemical analysis (Figure 3).
Lung tissue: cardiopulmonary block was extractedonce lungs were washed. The left
lung was expanded by intratracheal instillation of 10 ml formaldehyde with 20 cm H2O
pressure for histological analysis. On the other hand, the lower lobe of the right lung
was divided in 3 pieces and stored at -80ºC avoiding tissue deformation to perform gene
expression analysis (Figure 4).
Figure 2: Plasma collection procedure.
Blood
3500 rpm
10 min4˚C
2 ml
1 ml1 ml
Plasma
Cellular components
Store at-80˚C
N2
líquid
Alic.
Total and oxidized proteinsAcid sphingomyelinase activity
TNF-α IL-6 MCP-1 MIP-2
Material and Methods 88
Figure 3: Bronchoalveolar lavage free of cells (BAL) processing and isolation of
Pulmonary Surfactant fractions.
Figure 4: Lung tissue collection process: sampling to accomplish gene
expression and histological analysis.
Bronchoalveolarlavage
BAL
0,9 % NaCl
10 ml x 4
BAL
Pellet
400 g 10 min, 4˚C
Nº alveolar cells
% Alveolar macrophages
Total and oxidized proteinAcid sphingomyelinase activity
CRP TNF-α IL-6 MCP-1 MIP-2
Small aggregates
(SA)
Large aggregates
(LA)
Total proteinsTotal phospholipids
Cholesterol
Total proteinsSpecific pulmonary surfactant proteins Total phospholipidsLipid peroxidation
CholesterolInterfacial adsorption
48000 g 1 h, 4˚C
-80˚C
-80˚C-80˚C
Material and Methods 89
4. Arterial blood samples analysis.
Determination of arterial blood gases was accomplished using a blood gas analyzer
(Gem Premier 3000, IL Instrumentation Laboratory). Levels of lactate, glucose,
creatinine, lactate aminotrasferase (LDH) and creatinine kinase (CK) in arterial blood
were assessed using a chemical analyzer (Integra 700, Roche Diagnostics).
5. Alveolar fluid cells analysis
Cellular pellet obtained from bronchoalveola rlavage centrifugation was
resuspended in 1 ml of a solution 1:1, PBS: Streck Cell Preservative (Streck, Omaha,
USA). Total number of BAL cells was determined assessing cell viability with trypan
blue dye exclusion by counting in a Neubauer chamber (Marienfeld, Germany) using 15
l of cell suspension.
Flow cytometric analysis of BAL cells
Cells were washed with PBS, centrifuged at 1500 rpm during 10 min at 4ºC and
resuspended in a final volume of 2 ml of PBS. This cell suspension was used to assess
alveolar macrophages and neutrophils proportion in alveolar fluid cells using a
Fluorescence Flow Cytometer (FACScalibur, BD Biosciences, San Diego, USA).
This determination was accomplished performing a specific surface labeling using
the following specific monoclonal antibodies: mouse anti-rat CD11c (AbDserotec,
Oxford, UK), which recognizes specifically rat alveolar macrophages and mouse anti-
rat RP-1 (BD Biosciences, San Diego, USA), which binds to rat peripheral blood
neutrophils. Subsequently, cells were incubated under darkness conditions with a
fluorescein (FITC)-conjugated goat anti mouse IgG secondary polyclonal antibody
(AbDserotec, Oxford, UK).
In order to avoid unspecific unions, cells were incubated with RPMI media
supplemented with 10% bovine fetal serum (FBS) during 30 min previous to the
incubation with specific antibodies. Among incubations, cells were washed with PBS
and centrifuged at 1200 rpm during 5 min at 4ºC. Monoclonal antibody rat IgG2A
(AbDserotec, Oxford, UK) was used as negative control in both cases.
Material and Methods 90
After specific incubations, cells were washed and resuspended in 500µl of PBS.
10.000 total events were counted and analyzed using BD CellQuest Pro™ Software
(BD Biosciences, San Diego, USA) applying settings previously described to obtain
specific forward (FSC)/ sideward (SSC) scatter plots of alveolar fluid cells from rodents
(309, 310).
6. Histological analysis.
Samples preparation
Pulmonary hilium zones from the left lung were collected and fixed with formol
buffered 10% during 48h. Subsequently, samples were dehydrated performing an
increment alcohols procedure (70º-96º-100º), fixated with xilol and submerged in
paraffinduring 1h each process. Each paraffin block was cut in 7µm sections and stained
by haematoxylin-eosin technique. Briefly, samples were dewaxed with xilol and
rehydrated with decreasing graded alcohols procedure (100º-96º) during 10 min each,
before washed them with distilled water. Subsequently, samples were submerged in
eosin-phloxine during 5 min, dehydrated again by increment alcohols procedure and
fixated with xilol to assemble them. Slides were stored at room temperature, and
protected from light before use.
Injury score quantification
A modify injury score was used to quantify pulmonary damage (311, 312)
examining10 random fields for each section by light microscopy (40x). A score of 0, 1,
2or 3 was assigned if none, one, two or more than two membranes were found,
respectively. The mean of all values of the examined fields was assigned as a measure
of the degree of lung injury (305).
7. Isolation of large and small aggregates of pulmonary surfactant.
BAL was centrifuged at 100,000g for 1h at 4ºC in an ultracentrifuge XL-90
model (Beckman Coulter, Fullerton, USA) to separate the large surfactant aggregates
(LA) constituted by multilamelar vesicles of phospholipids and PS specific
apolipoproteins SP-A, SP-B and SP-C (313) from the small non-functional surfactant
Material and Methods 91
aggregates (SA), which remain in the supernatant (314)(Figure 3). The resulting
precipitate, LA fraction, was resuspended with 400 μl of saline 0.9%, reconstituted with
a potter and aliquoted and stored at -80ºC. 2 ml of supernatant, SA fraction, were
collected stored at -80ºC until it analysis.
8. Total amount of phospholipids quantification.
Lipid extraction was performed to determine the content of total phospholipids (PL)
in LA and SA, by chloroform-methanol extraction (315) using 1 ml of SA and 50 µl of
LA led to 1 ml by adding NaCl 0.9%. The organic phase of each sample was evaporated
with a rotary evaporator R (Büchi, Flawil, Switzerland) and resuspended with 1 ml of
chloroform/methanol (2/1, v/v). Total amount of PL from SA and LA was assessed
from the organic extracts obtained by an analysis described by Rouser and col. (316) of
phosphorous quantification.
Briefly, samples (200µl of LA and 300 µl of SA) and standards (KH2PO4 0.05
mg/ml) were dried in a sand bath before adding 450 µl of perchloric acid 70% (HClO4)
and incubate covered during 30 min at 260ºC to accomplish the mineralization of the
phosphorous. The quantification of mineralized phosphorous was achieved through a
colorimetric reaction by adding ammonium molybdate (2.5%, w/v) which conform a
complex with phosphorous. This complex was reduced by adding ascorbic acid (10%,
w/v), which formed a colored compound after 8 min at 100 ºC of incubation stooped
with ice. Absorbance was measured at 820 nm in a spectrophotometer model DU 800
(Beckman Coulter, Fullerton, USA) and color absorbance values were directly related to
phosphorous concentration by interpolation into a calibration curve built with known
concentration standards.
9. Lipid peroxidation assessment.
Lipid hydroperoxides (LPO) present in the organic extracts of LA were assessed by
the FOX method (317). This process is based on the ability of LPO to oxidize Fe2+
to
Fe3+
. This oxidation is detected using thiocyanate ion as chromogen. To this purpose we
used the Lipid Hydroperoxides Kit from Cayman (Cayman Chemical Company, Ann
Arbor, USA). Samples (1.5 nmol PL/l) and standards (13-hydroperoxy acid-
Material and Methods 92
octadecadienoic acid [13-HpODE] 50M) were incubated covered during 5 min at room
temperature (RT), with 4.5 mM ferrous sulfate reagent in 0.2 M hydrochloric acid and
ammonium thiocyanate 3% methanol (v/v). Absorbance at 500 nm was measured in a
spectrophotometer model DU 800 (Beckman Coulter, Fullerton, USA)and color
absorbance values were directly related to LPO concentration by interpolation into a
calibration curve built with known concentration standards (0 to 5 nmol/mlof 13-
HpODE).
10. Cholesterol quantification.
The presence of cholesterol (Ch) in LA and SA was determined by a colorimetric
enzymatic assay using the CHOD-POD Enzymatic Colorimetric kit (Spinreact,
SantEsteve de bas, Spain). The method is based on the cholesterol oxidase activity in a
set of chained reactions ending in the formation of a colored compound. A first reaction
is performed by cholesterol esterase, which breaks down Ch esters into Ch and fatty
acids. Total free Ch in each sample is then oxidized by cholesterol oxidase into 4-
cholestenone and H2O2. The colorimetric reaction takes place between H2O2, phenol
and 4-aminophenazone to produce quinonimine, a substance with a rosy color. Briefly,
10 µl of Ch standard (200 mg/dl), LA and SA (1:10) samples were mixed with 1 ml of
reactive mixture containing the enzymes above mentioned in a PIPES buffer pH= 6,9
and phenol. This mixture was gently blended and incubated during 10 min at RT until
its absorbance lecture at 505 nm in a spectrophotometer model DU 800 (Beckman
Coulter, Fullerton, USA).
11. Total protein determination.
Total content of protein was determined in BAL, LA and SA samples by a
colorimetric reaction based in Lowry method (318), modified by adding sodium
dodecyl sulfate (SDS). This method is based on the denaturalization and exposition of
protein tyrosine phenolic groups by copper ions under alkaline conditions. Therefore,
samples and standards (albumin) were mixed with a solution composed by sodium
tartrate 2% (w/v), cupric sulfate 1% (w/v), sodium carbonate 2% (w/v) and one pellet of
sodium hydroxide (Merck, Darmstadt, Germany) and incubated for 15 min at RT.
Material and Methods 93
Subsequently, they were incubated during 30 min with Folin-Ciocalteau reactive
(Merck, Darmstadt, Germany), turning the yellow color of Folin-Ciocalteau reagent into
blue due to Folin-Ciocalteau reduction by tyrosinresidues. The absorbance was read at
700 nm with a spectrophotometer model DU 800 (Beckman Coulter, Fullerton, USA)
and color absorbance values were directly related to protein concentration by
interpolation into a calibration curve built with known concentration standards.
12. Oxidized proteins quantification.
The presence of oxidized proteins in BAL was determined evaluating their carbonyl
content by a spectrophotometric assay binding 2.4-dinitrophenylhydrazine (DNPH)
(319). DNPH reacts with protein carbonyls, forming a Schiff base to produce the
corresponding hydrazone, which can be analyzed spectrophotometrically. Therefore,
100 µl of BAL samples per duplicate were incubated with DNPH 10mM in HCl 2.5 M
during 1 h at RT in darkness and mixed every 15 min. Then, samples were precipitated
with trichloroacetic acid (TCA) at 10% during 5 min in ice and subsequently they were
centrifuged at 10.000g during 10 min at 4ºC and washed with ethanol/ethyl acetate (1:1,
v/v). Finally, proteins were solubilized in 500 µl of guanidinium hydrochloride 6M
(FlukaBiochemika, Buchs, Switzerland) and centrifuged at 10.000g for 10 min at 4°C to
remove insoluble material traces. Carbonyls were measured spectrometrically at 370 nm
in a spectrophotometer model DU 800 (Beckman Coulter, Fullerton, USA). The
determination of carbonyls concentration was assessed by inserting the absorbance of
each sample into the following equation: Protein Carbonyls (mol/ml) =
[(Abs.)/0.022µM-1
cm-1*
] * [500µl (resuspension vol.)/ 100µl (sample vol.)]*
The actual
extinction coefficient for DNPH at 370nm.
13. Damage markers quantificationin BAL and plasma:
TNF-α
TNF-α presence was evaluated in BAL and plasma samples in duplicated, using the
same volume in both types of samples. This valuation was assessed with the BD
Biosciences ELISA Colorimetric kit (San Diego, CA, USA) TNF-rat specific. A
polystyrene plate (Maxisorp ®, Nunc, Rochester, USA) was incubated overnight (o/n)
Material and Methods 94
at 4ºC with a monoclonal antibody anti-TNF-α. The next day, after a washing process
with PBS/Tween-20 0.05% (v/v), the plate was blocked for 1 h at RT with PBS/FBS
10% (v/v) to prevent non-specific binding. Then, the plate was incubated for 2h at RT
with the samples and the calibration curve formed by the TNF-α standard between 2000
to 31.25 pg/ml. After this period, a new washing step was performed to remove
unbound protein followed by an incubation with a second anti-TNF-α biotinylated
during 1h. Subsequently, another wash was done to remove unbound antibody and the
plate was incubated 30 min with a streptavidin-peroxidase reagent, which binds to the
biotinylated antibody, until it was washed for the last time, to remove unbound
reagent.Finally, the plate was developed with tetramethylbenzidine (TMB) and once the
reaction was stopped with 2N sulfuric acid and phosphoric acid 1M, the absorbance was
read at 450nm in the plate reader DIGISCAN ELISA plates (AsysHitech GmbH,
Eugendorf, Austria).
IL-6
The amount of IL-6 was determined in BAL and plasma samples in duplicate, using
the same volume of sample, being the plasma previously diluted ½. This quantification
was assessed using a Quantikine ELISA kit Rat IL-6 Immunoassay (R&D Biosystems,
Minneapolis, USA). First, it was mixed 50 ul of PBS/FBS 10% (v/v) with 50 ul of the
samples and 50 ul of the IL-6 standard to perform a standard curve (2000 to 62.5 pg/ml
IL-6 standard) in a polystyrene plate whose wells have bound a monoclonal antibody
anti-rat IL-6. The plate was incubated for 2h at RT. Subsequently, after a wash with
PBS/Tween-20 0.05% (v/v) to remove unbound protein, the plate was incubated another
2h at RT with a second polyclonal anti-IL-6 coupled to peroxidase, which binds to the
IL-6 antibodies previously attached to the plate. After this period, a new washing
process was performed to remove unbound antibody and then, the plate was incubated
half hour with a reagent mixture made 15 min prior to use, containing hydrogen
peroxide and TMB. Finally, the reaction was stopped with dilute hydrochloric acid and
the absorbance was read at 450nm in the plate reader DIGISCAN ELISA plates
(AsysHitech GmbH, Eugendorf, Austria).
MCP-1
The amount of MCP-1 was evaluated in BAL samples (dilution ½) and in plasma
(¼ dilution) samples in duplicate, using the same sample volume. This quantification
Material and Methods 95
was carried out using a Quantikine ELISA kit JE/MCP-1 Rat Immunoassay (R&D
Biosystems, Minneapolis, USA). First, 50 ul of the samples and 50 ul of the standard
curve (500 to 15.6 pg/ml MCP-1 standard) were mixed with 50 ul of PBS/FBS 10%
(v/v) in a polystyrene plate whose wells having attached a monoclonal antibody to rat
JE/MCP-1 and incubated for 2h at RT. Subsequently, after washing the plate with
PBS/Tween-20 0.05% (v/v) to remove unbound protein, the plate was incubated for 2 h
at RT with a second antibody polyclonal anti-rat JE/MCP-1 coupled to peroxidase,
which joins the MCP-1 previously bound to the antibodies attached to the plate. After
this period, a new washing process was performed to remove unbound antibody and
then the plate was incubated during 30 min with a reagent done 15 minutes prior to use,
containing hydrogen peroxide and TMB. The reaction was stopped with dilute
hydrochloric acid and the absorbance was read at 450nm in the plate reader DIGISCAN
ELISA plates (AsysHitech GmbH, Eugendorf, Austria).
MIP-2
MIP-2 was determined in BAL and plasma samples in duplicate, using the same
sample volume. This quantification was assessed using a Quantikine ELISA kit Rat
CINC-3 Immunoassay (R&D Biosystems, Minneapolis, USA). Initially, 50 ul of the
samples and 50 µl of the standard curve (1000 to 31.2 pg / ml CINC-3/MIP-2 standard)
were added in a polystyrene plate and mixed with 50 ul of PBS/FBS 10% (v/v). The
samples were incubated for 2 h at RT in this plate, whose wells are attached to the
specific monoclonal rat antibody CINC-3/MIP-2. Then, after washing with PBS/Tween-
20 0.05% (v/v) to remove unbound protein, the plate was incubated for 2h at RT with a
second polyclonal antibody anti-CINC-3/MIP-2 coupled to peroxidase that will stick
with the MIP-2 antibodies previously attached to the plate. Subsequently, a new wash
process was performed to remove unbound antibody and then, the plate was incubated
30 min with a reagent containing a mixture of hydrogen peroxide and TMB made 15
minutes before use. The reaction was quenched with dilute hydrochloric acid and the
absorbance was read at 450nm in the plate reader DIGISCAN ELISA plates
(AsysHitech GmbH, Eugendorf, Austria).
Material and Methods 96
C-reactive protein
C-reactive protein (CRP) was measured in BAL samples in duplicate, using a
specific rat ELISA kit of Chemicon (Millipore, Billerica, USA). To perform this assay
the same volume was used in both types of samples being diluted at least 1:20 the BAL
samples. First, samples and standards (133.3 to 4.9 mg/ml to perform a curve) were
incubated for 30 min at RT in a polystyrene plate whose wells have attached a specific
rat antibody anti-CRP. After a washing process with PBS/Tween-20 0.05% (v/v) to
remove the unbound proteins, a second anti-CRP antibody coupled to peroxidase was
incubated for 30 min at RT in order to bind the CRP previously bonded to the antibody
attached to the plate. Finally, after another washing process, the plate was incubated
with TMB developing reagent and the reaction was stopped with phosphoric acid for
read the absorbance at 450nm in an ELISA plate reader DIGISCAN (AsysHitech
GmbH, Eugendorf, Austria).
14. Acid Sphingomyelinase activity determination.
Acid sphingomyelinase (ASMase) activity was determined in BAL and plasma
samples performing an enzymatic assay. This assay is based on the ASMaseactivity,
which catalyze the hydrolysis of radio labeled sphingomyelin (SM) to ceramide and
radio labeled phophocholine.
To this end, first it was dried by evaporation 10.15 nmoles of sphingomyelin (SM)
composed by unlabeled SM (Sigma-Aldrich, St. Louis, USA) and [N-methyl-14C] SM
(0.15 nmol ([N -methyl-14 C] sphingomyelin, 0.74 μCi/mol (GE Healthcare,
Buckinghamshire, UK). Then, the SM was rehydrated in 90 µl of a buffer composed of
0.2M sodium acetate pH 5, 0.5% Triton X-100 and 0.1 M zinc chloride, for 1 h at 45°C
under continuous shaking. The rehydrated SM was gently mixed with 10μl of BAL or
plasma samples before incubate them 2 h at 37ºC to carry out the enzymatic reaction.
Subsequently, the enzymatic reaction was stopped performing an organic extraction
(section 8) (320) and it was collected the upper aqueous phase containing 14C-
phosphocholine in a liquid scintillation vial (MP Biomedicals, Irvine, USA).Finally, the
cpm of the samples were quantified in a liquid scintillation ISODATA gamma counter
(Polymedco, Inc., Cortlandt Manor, USA) for 5 min/tube.
Material and Methods 97
15. Determination of PS-associated proteins SP-A, SP-B and SP-C levels by
Electrophoresis and Western blot analysis.
To analyze the levels of specific surfactant proteins SP-A, SP-B and SP-C, first an
electrophoretic analysis of LA samples was performed by one-dimensional sodium
dodecyl sulfate-polyacrylamide gel electrophoresis, using running gels of 12% for SP-A
and SP-B, and 18% for SP-C. Reducing conditions (5% β-mercaptoethanol) were used
for SP-A analysis and 1 μg of total protein was applied. In the case of SP-B and SP-C,
the same amount of PL (5 nmol for SP-B and 3 nmol for SP-C) was applied. After
electrophoresis, samples were transferred to a nitrocellulose membrane (SP-A and SP-
B) or a polyvinylidenedifluoride membrane (PVDF) (SP-C) using a Bio-Rad Transblot
Cell (Bio-Rad, Hercules, USA). The transfer was performed at 300mA constant during
1h, using 25 mMTris-HCl, pH 8.3, 192 mMglycine, and 20 % (v/v) methanol as transfer
buffer.
PS-associated proteins immunodetection was performed using the SNAPTM
i.d.
System (Millipore Corporation, Bedford, USA). For this purpose, blots were assembled
in a hydrated holderand placed in the system chamber with the well side up. Rapidly,
blots were blocked with a PBS containing 0.05% of low fat dry milk. Immediately, the
vacuum was applied and, when the well was emptied, it was realized a washing step
with PBS/Tween-20 0.1% (v/v) without turn off the vacuum. When the well was
completely empty, the vacuum was turned off and the incubation of the primary
antibody during 10 min was performed. To this, we used the following polyclonal
antibodies developed in rabbit: anti-porcine-SP-A, anti-porcine-SP-B and anti-
recombinant-human-SP-C. Subsequently three washing steps were performed before
incubate during 10 min with the vacuum off with the second antibody anti-rabbit-IgG
coupled to peroxidase (Sigma-Aldrich, St. Louis, USA). Finally, another wash step was
performed and the blots were removed from the holder system and incubated with the
chemiluminescent detection reagent ECL (Western Immobilon, Millipore Corporartion,
Bedford, USA) for 1 min. In all cases, proteins were visualized by superimposing a film
on the blot to carry out its development in the developing machine (Curix 60, Agfa,
Mortsel, Belgium).
Quantification was achieved by densitometric evaluation using Quantity One
software (Bio-Rad Laboratories, Hercules, USA).
Material and Methods 98
16. Gene expression analysis by real time–PCR.
Total RNA was isolated from the lower lobe of the right lung using the RNeasy
plus Mini Kit (Quiagen, Hilden, Germany) according to the protocol provided by the
supplier. Lung tissue was weigh and freeze with N2 liquid to immediately pulverize it
using a mortar and pestle underRNase-free and freezing conditions. Grind powder was
homogenate using a lysisbuffer provided by the supplier containing β-Mercaptoethanol
(1:100) and a sterile needle (25-gauche). The homogenate was centrifuged 3 min at
16000g at RT and the supernatant was transfer to gDNA eliminator columns (used to
eliminate DNA traces) provided by the supplier and centrifuged 30 sec at 8000g at RT.
The fluid was collected, mixed with ethanol 70% and transferred toRNeasy
spincolumns, which retain RNA in the membrane. Columns were centrifuged 30 sec at
8000g at RT until all the fluid had passed and the eluate was discarded. Subsequently a
wash process was performed and columns were treated with the RNase-free DNAse Set
(Quiagen, Hilden, Germany) during 20 min to remove possible DNA contaminations.
After several wash steps, columns were centrifuged 1min at 16000g to eliminate traces
and finally the RNA was eluted with 40μl RNase-free water supplied. The amount of
RNA extracted was measured at 260 nm in a spectrophotometer ND-1000 (NanoDrop
Technologies, Wilmington, USA).
cDNA synthesis was performed with the Transcriptor High Fidelity cDNA
Synthesis kit (Roche, Mannheim, Germany) using 1µg total RNA as input. The RNA
was first incubated at 65ºC during 10 min (RNA denaturalization) in a Thermal-cycler
C-1000(Bio-Rad, Hercules, USA) with the random hexamer primers supplied. Then, it
was added a master mix containing: Transcriptor RT Reaction Buffer (5x), protector
RNase inhibitor (40U/μl), deoxynucleotide mix (10mM) and transcriptor reverse
transcriptase. All was gently mixed and tubes were incubated with the following
thermo-cycling program: 25ºC during 20 min (primers annealing), 55ºC for 1 h (cDNA
synthesis) and 85ºC during 5 min (enzyme inactivation). Then, the cDNA was stored at-
20ºC until the PCR design.
Real-time PCR (RT-PCR) was developed using the Universal Probe Library
technique (Roche, Mannheim, Germany). This method is based on the identification
ofimput sequences of the target genes using the ProbeFinder online software provided
by Roche (www.universalprobelibrary.com). This software designs an optimal qPCR
Material and Methods 99
assay combining the best probes and primers according to their organisms specificity,
absence of cross-hybridations, intron-spanning amplicon, and a small amplicon size.
The primers selected by this software were analyzed and re-design in some cases using
PrimerSelect application (Lasergene Core Suite Software, DNASTAR, Madison, USA)
and finally ordered to be synthesized (Sigma-Aldrich, St. Louis, USA) (Table.1).
RT-PCR was performed in triplicates using the appropriate probes and primers (20
μM) for each target gene, mixed with FastStart Universal Probe Master (Rox, 2x)
(Roche, Mannheim, Germany) to reach a final volume of 8μl. Allsample mixes (10l)
were gently blended and transferred to a 384-well microplate (Applied Biosystems, Life
Technologies, USA) which was incubated with the following thermo-cycling program:
94ºC during 10 min (initial DNA molecule denaturalization), 94ºC for 10sec (DNA
denaturalization) and 60ºC during 45 seg (primer annealing and DNA chains extension),
being repeated 40 times the two last steps in The LightCycler® 480 Real-Time PCR
System (Roche, Mannheim, Germany).
Results were analyzed using the ∆∆CT method (321), normalizing with the
expression levels of β-actin. The final data were represented as the normalized fold
change expression.
Target gene Primer Forward Primer reverse Probe
SP-A 5´-CAAGGGAGAGCCTGGAGAAAG-3´ 5´-CTGAGGACTCCCATTGTTTGC-3´ 50
SP-B 5´-CTGATCAAGCGGGTCCAAGC-3´ 5´-GGCAGATGCCACCCACCAC-3 ́ 76
SP-C 5´-GTAGCAAAGAGGTACTGATGG-3´ 5´-CACGATGAGAAGGCGTTTGAG-3´ 74
ASM 5´-CAGCCTTATGGTCCTTTCAG-3´ 5´-CAGGATTGTTGGTCTCTTTTTC-3´ 62
MMP-2 5´-CGTAACTCCACTACGCTTTTC-3´ 5´-CTTGCCGTCAAATGGGTATC-3´ 60
TGF-β1 5´-CCTGGAAAGGGCTCAACAC-3´ 5´-CGTACACAGCAGTTCTTCTC-3´ 1
β-ACTIN 5´-GGCCAACCGTGAAAAGATGAC-3´ 5´-GACCAGAGGCATACAGGGAC-3´ 64
Table 1: Primers and probes design with the ProbeFinder software by Roche used to realize
real-time-PCR assays.
Material and Methods 100
17. Biophysical function of Pulmonary Surfactant.
Interfacial Adsorption:
The ability of LA to adsorb onto and spread at the air–water interface was tested at
25ºC in a Wilhelmy-like high-sensitive surface microbalance, coupled to a King-
Clements Teflon dish (322, 323) (Figure 5). 450 nmol of LA phospholipids from each
samplewas injected into the hypophase chamber of the Teflon dish containing 6 ml of
buffer (pH 7.0) composed by 5 mM Hepes, 150 mM NaCl, and 5 mM CaCl2, altogether
under continuous stirring to avoid diffusion from being the limiting step of adsorption.
Interfacial adsorption was measured following the variation in surface pressure () as a
function of time, using a platinum plate coupled to the microbalance (KSV
Instruments). The surface pressure () is related to the surface tension () by the
following expression: = 0-, where
0is the surface tension of the liquid in the air-
liquid interface without the surfactant presence, which its value is 72 mN/m. Therefore,
when PS establish a monolayer in the air-liquid interface, the surface tension decreases
up to the equilibrium values between 22-25 mN/m and consequently, the arise
values between 47-50 mN/m.
Figure 5: Schematic representation of a Wilhelmy microbalance for interfacial adsorption
measurements.
Material and Methods 101
Captive Bubble surfactometer
Captive bubble surfactometer (CBS) is an experimental set up designed to evaluate
the surface activity of surfactant when it is adsorbed onto the air-liquid interface of an
air bubble enclosed in a controlled environment chamber. This system, not only
emulates the air-liquid interface of alveoli and its movements during respiration, but
also allows controlling several parameters such as temperature, humidity or pressure,
essentials for the adequate surfactant functionality.
CBS was designed, built and optimized in the late 80's by Dr. Samuel Schürch in
order to study the behaviour of the native and synthetic surfactant films in physiological
relevant conditions (324).
Surface area (Ab), volume (Vb) and surface tension of the bubble(γb)are calculated
in the CBS from the diameter and height of it, by monitoring, recording with a video-
camera (Model 765, Pulnix USA), and then digitizing with the computer software
CBpost Ver1.5 © (325)
Dr Samuel Schürch and Michael Schoel from the University of Calgary in Canada,
built the CBS setup used in the experiments done in this thesis, for the Complutense
University of Madrid.
Components of the CBS system (Figure 6):
The chamber is a glass cylinder fixed to a metal base with a 2 mm hole in diameter
at the bottom, through which the air bubble is created (0.0035 to 0.040 cm3). The other
side of the chamber is sealed with anagarose plug (1%, w/v) to create a hydrophilic
environment that prevents the adhesion of the bubble. The agarose capis adjusted to a
piston, which will start to compress and expand the space between the plug and the
metal base, when initiating experimental process.
This system is filled with approximately, 1.5 mL of a monolayer buffer (Tris 5 mM,
NaCl 150 mM) containing sucrose 10% in order to increase the density of the aqueous
subphase, leading the surfactant against the bubble and avoiding its dilution in the
subphase. Besides, the chamber is placed in a metallic jacket used as a water bath
thermostated by a heat external source strictly controlled by the computer. This jacket
Material and Methods 102
also has a transparent side that allows observe the bubble and locate the IR video
camera in front of it. This complex is positioned and adjusted by two screws in a holder
to begin the procedure.
Experimental protocol:
Before starting the experimental protocol, a degasification procedure was essential
to ensure that any other bubble alters the results. This step involves the expansion of the
bubble in the sealed chamber for 10 min, to allow small bubbles formed in the aqueous
subphase join the expanded one.
To accomplish CBS experiments we used LA samples with a concentration of 20.0
2.5 mg/ml of PL. This value was determined as a critical concentration to observe
differences between groups.
The CBS allows determining if the surfactant measured fulfills its dynamic
properties, which are:
Very rapid interfacial adsorption (Initial adsorption)
Low surface tension upon compression (less than 2mN/m) (Dynamic cycles)
Efficient re-extension upon expansion. (Post-expansion adsorption)
Figure 6: Schematic representation of the CBS device (A) and a detailed view of the bubble
chamber (B).
Material and Methods 103
As a result, the protocol used simulates each feature respectively accomplishing the
following steps:
(I) Initial adsorption (IA) kinetics: registers the ability of the surfactant to reach the
interface and form a film able to reduce the surface tension to the equilibrium. PS
(150 nL) is applied with a syringe connected to a transparent capillary close to
the bubble without contact, transferring the material onto the interface. This event
can be visualized through the changes in the bubble shape during 5 min after the
aplication of the material. The more flattens the bubble, the more surface tension
is reduced. Therefore, the equilibrium surface tension reached with surfactant
presence of 22-23 mN/m in less than 5 sec, from the inicial surface tension of the
aqueous subphase of 70 mN/m (Figure 7).
(II) Post-expansion adsorption (PEA) kinetics: allows analyzing the reorganization
and spreading of surfactant in an enlarged interface. To that purpose, after the
initial adsorption experiment, the chamber is carefully sealed and, the bubble
volume is re-determined before expanding the bubble to a maximum size of 0.15
cm3
controlled by the software. After the bubble expansion, the changes in
surface tension were registered during 5 min, visualized by the changes in the
bubble shape described previously in IA (Figure 8).
Figure 7: Initial Adsorption:
changes in the surface tension
detected by the alteration of
the bubble shape.
Figure 8: Post-expansion
adsorption:changes in bubble
shape due to decrease of
thesurface tension in function
of time during the subsequent
adsorption to expansion.
Material and Methods 104
(III) Quasi-static compression and expansion cycles: the air bubble is subjected after
the adsorption of the surfactant, to four discrete step-wise compression-expansion
consecutive cycles to permit the relaxation and reorganization of the material
after each area change. This step, permits to analyze in detail the behaviour of
surfactant, as consequence of using cycling speeds much slower than those
associated with breathing, which allows the detection of structural features such
as phase changes, three-dimensional restructuration and progressive purification
of interfacial films.
To this purpose, first the initial bubble volume was established as the maximum
bubble volume during PEA. Then, the bubble was compress up to the volume required
to achieve the minimum surface tension without reaching the interfacial film collapse
(Figure 9). This event can be detected because the bubble area decreases without
reducing the surface tension. Therefore, the cycles were performed with 1 sec delay
between de compression steps and reducing 20% its previous volume.
Usually, the first quasi-static cycle is different from the other three, because
presents a higher hysteresis loops. This means that the energy provided by the
compression is used to reorganize the material at the interface and purifies the material
instead of reducing the surface tension. In addition, thanks to this event, subsequent
cycles will show progressively lower hysteresis and less compression will be needed
to reduce the surface tension to minimum.
Figure 9: Quasi-static
compression and expansion
cycles: changes in the bubble
shape related with the surface
tension/ area isotherms obtained
during the quasi-static cycling
process.
Material and Methods 105
(IV) Compression and expansion dynamic cycles: reproduces the compression-
expansion of continuous cycles, simulating the physiological human respiratory
rates (20 cycles/min) in order to observe the real stability and functionality of the
surfactant in the interface (Figure 10). In the present study, 20 cycles/min were
performed according to previous CBS studies in high-stretched rats (326) and the
cycles 1, 10 and 20 were represented. This step was carried out after ending the
quasi-static cycles, using the maximum and minimum volumes of the quasi-static
cycles.
A functional surfactant decreases the surface tension to the maximum recurrently
with the minimal compression and exhibiting reduced hysteresis, despite the speediness
of the cycles that avoids the possibility of relaxation or reorganization.
18. Statistical analysis
Data are represented as mean standard error of mean (SEM) of individual
measurements. Means were normally distributed (Shapiro-Wilk test). Differences
between means of each group were analyzed using a one-way analysis of variance
(ANOVA) followed by a Bonferroni pos hoc analysis. A two-tailed unpaired Student´s
T test was performed when required. A confidence level of 95% or greater (p< 0.05)
was considered significant. The statistical analysis was performed using Sigma Plot
11.0 statistical software.
Figure 10: Dynamic compression
and expansion cycles: changes in
the bubble shape associated with
the surface tension/ area isotherms
achieved during the
dynamiccycling process.
Material and Methods 106
107 Chapter 1
Chapter 1
Characterization of alveolar
injury due to high-stretch
ventilation
108 Chapter 1
109 Chapter 1
1. ABSTRACT
The aim of this study was to characterize changes produced in the alveolar
compartment due to injurious high-stretch ventilation.
Sprague-Dawley rats were randomly assigned to control conditions [no
mechanical ventilation (n=15)], low-stretch [VT = 9 ml/kg, positive-end expiratory
pressure (PEEP) = 5 cm H2O (n=24)] or high-stretch [VT = 25 ml/kg, PEEP = 0 cm
H2O (n=24)] ventilation strategies and monitored for 150 min. Subsequently, lung
tissue, plasma, bronchoalveolar fluid (BAL), BAL cells, and isolated surfactant were
analyzed.
The high-stretch ventilation group, presented several factors implicated in acute
lung injury, such as leakage of proteins into the alveoli, release of inflammatory
mediators, oxidative stress in the alveolar compartment, decrease of alveolar fluid
cells and hyaline membranes deposition, together with factors involved in the
alteration of pulmonary surfactant system such as protein contamination, surfactant
oxidation and decrease of surfactant-associated proteins, as depicts alteration of
surfactant metabolism and its biophysical function impairment. All this alterations in
the alveolar space are coupled with impaired gas exchange and decrease in dynamic
compliance, rendering the lung susceptible to atelectasis. Furthermore, we detected
slightly alterations in the low-stretched group like decrease of alveolar fluid cells and
increase of some damage markers in the alveolar space.
This study indicates that injurious high-stretch ventilation produces direct
damage to the lung, promoting inflammation, oxidative stress, edema and release of
factors that together inactivate pulmonary surfactant. Lung surfactant impairment
leads to atelectasis as depicted by impaired gas exchange and decrease in dynamic
compliance.
2. INTRODUCTION
The acute respiratory distress syndrome (ARDS) and acute lung injury (ALI) are
common respiratory syndromes in critically care units associated with elevated
mortality rates (47). However, their only effective treatment to date is mechanical
ventilation (MV) (173). Thus, many studies have been undertaken in order to improve
the ventilator strategies and therefore achieve a decrease in their currently mortality
110 Chapter 1
rates of 43% (47, 168, 173). However, these researches also discovered that ventilate
with certain strategies characterized by high tidal volumes (VT) or lack of positive
end-expiratory pressure (PEEP) administration lead to aggravate and even develop
lung damage per se, outcome denominated ventilator-induced lung injury (VILI) and
widely used as animal model of ALI characterization (7). Since then, a wide range of
VILI models has been conducted in order to elucidate the main factors attributable to
this alteration.
As a result, a large number of studies concluded that tissue injury, characterized
by thickening of the alveolar wall or alveolar type I cells necrosis, is a main feature of
VILI, which is tightly linked to alterations in alveolar-capillary barrier permeability
(235). In particular, the alteration of the alveolar–capillary barrier is an important
mechanism responsible of alveolar edema presence, which is characteristic of VILI
(236, 327). Also, many other studies highlighted some physiological data, such as
hypoxemia, as a key feature of VILI (328).
On the other hand ,the role of the innate immune response and inflammation in
VILI has been broadly studied, being demonstrated that most of alveolar cells are
capable to release inflammatory mediators, including IL-1β, IL-6, IL-8, IL-10 and
TNF-α (238). However this field remains controversial, as some studies observed an
increase of cytokines release in lungs ventilated without PEEP (250) whereas other
studies reported no association between VILI and productionof proinflammatory
cytokines in the same animal model (257).
As well, different studies were focused on elucidate the role and outcome of
pulmonary surfactant (PS) in VILI. PS is a surface-active lipoprotein complex
secreted as its active fraction, called large aggregates (LA), by alveolar type II cells
(ATII), which accomplish its main function: to stabilize the alveoli by the reduction
of surface tension at the air-liquid interface, preventing the alveolar collapse during
end-exhalation (329). Several in vivo and ex vivo investigations concluded that PS
biophysical function is impaired in VILI (295-298, 330). Ex vivo studies, determined
together with PS dysfunction some alterations in PS metabolism and composition,
such as cholesterol increase in LA or hydrophobic PS-associated proteins RNA levels
decrease (295, 297, 330). Conversely, fewer studies have been conducted in vivo,
detecting similar alterations (296, 298). Therefore, further investigation must be done
in order to elucidate the mechanisms and factors that lead PS alterations in VILI.
111 Chapter 1
Therefore, the aim of the present study was to characterize the impact of high-
stretch ventilation in the alveolar space and in particular its effects on the
composition, structure, and functional activity of lung surfactant assessing the causes
of surfactant alterations.
To accomplish this objective, we characterize physiological, histological,
inflammatory and PS changes in an in vivo model using injurious (VT = 25mL/kg, no
PEEP) ventilator strategies or conventional strategies (VT = 9 mL/kg, PEEP = 5
cmH2O) resembling clinical situations (10).
3. EXPERIMENTAL DESIGN
We established three experimental groups:
1) Control group: animals subjected to identical anesthetic and surgical procedures
without being mechanical ventilated (n=15).
2) Low VT ventilated group: VT = 9 mL/kg, PEEP = 5 cm H2O (n=24).
3) High VT ventilated group: VT = 25 mL/kg, zero PEEP (n=24).
Figure 1: Experimental design. Representation of all groups established subdivided
according to mechanical ventilation strategies.
Experimental design
t: 0 min t: 150 min
HV
n=24
VT = 25 ml/kg, 0 PEEP
Settling time
30 min
Settling time
30 min
t: 0 min t: 150 minLV
n=24
VT=9 ml/kg, 5 cmH2O PEEP
C: non-ventilated rats.
n=15.
112 Chapter 1
In both MV groups, respiratory rate was 70 bpm, inspiratory time 0.3 seconds,
expiratory time 0.56 seconds and FiO2 0.35.
Animals were ventilated for an equilibration period of 30 min using the low VT
ventilation parameters. Then, they were assigned randomly to one of the groups.
Dead-space ventilation was increased in animals ventilated with high VT (by
increasing the length of the ventilatory circuit) to attain comparable values of PaCO2
during the ventilation period. The assigned VT was administered starting at t=0 min
up to 150 min.
At t=0 min and t=150 min, mean arterial pressure (MAP), peak airway pressure
[PAW], and dynamic respiratory system compliance [CRS]) were registered. Blood
samples were drawn at t=150 min to assess biochemical and gases analysis.
Animals were sacrificed by exsanguination after 150 min and subsequently we
proceeded to sampling. We obtained lung tissue and bronchoalveolar lavage that it
was separated from the alveolar fluid cells by centrifugation. The remaining
bronchoalveolar lavage free of cells (BAL) was processed to obtain PS.
4. RESULTS
4.1. Physiology
Lung functionality was determined by hemodynamic and ventilatory
measurements in both groups of study.
Ventilator parameters (PAW, CRS) and MAP were measured at the start and end of
the ventilation period. As depicted in Table 1, rats ventilated with high VT showed a
significant increase in PAW over time, as well as a significant decrease in CRS and
MAP.
Arterial blood gases, pH and lactate concentration were measured in blood at the
end of MV. Rats exposed to high VT MV presented systemic acidosis, hypoxemia and
hyperlactatemia in contrast with rats ventilated with low VT (Table 1). Specifically,
PaO2/FiO2 ratio was below 300 mmHg in high-stretched rats (data not shown), criteria
defined by the ARDSnet (2).
All these data suggest the existence of atelectasis in the animals ventilated with
high VT.
113 Chapter 1
Table1: Changes in mechanical ventilatory parameters (PAW, CRS), mean
arterial pressure (MAP), blood gases and lactate concentration in rats exposed to
Low (VT= 9 mL/kg) or High (VT=25 mL/kg) mechanical ventilation strategies.
Low VT High VT
PAW (cmH2O) t=0
t=150
17.36±0.38
17.36±0.31
28.86±0.72
36.50±1.96 *
CRS (mL/cmH2O) t=0
t=150
0.32±0.01
0.32±0.01
0.44±0.02
0.34±0.03 *
MAP (mmHg) t=0
t=150
114.16±4.23
114.04±4.49
115.59±4.49
71.15±6.32 *
PaO2 (mmHg) t=150 146.75±3.37 88.00±12.32 #
PaCO2 (mmHg) t=150 30.35±1.17 39.13±1.14
pH t=150 7.42±0.01 7.29±0.02 #
Lactate (mmol/L) t=150 1.53±0.11 2.63±0.44 #
Definition of abbreviation: PAW: peak airway pressure; CRS: respiratory system
compliance; MAP: mean arterial pressure; PaO2: partial pressure of arterial oxygen;
PaCO2: partial pressure of arterial carbon dioxide.
PAW, CRS and MAP were measured at baseline (t=0) and after 150 minutes of
mechanical ventilation. PaO2, PaCO2, pH and lactate concentration were measured at
t=150 min. Data are mean ± S.E.M. * p<0.05, t=0 vs. t=150 min; #p<0.05 Low VT vs.
High VT.
4.2. Alveolar injury
Several parameters were evaluated in order to characterize the injury induced by
high VT ventilation.
114 Chapter 1
4.2.1. Cellular and histological analysis
Total cell counts in the alveolar fluid were significantly decreased in MV groups
(p<0.001), having significant differences between them (p<0.05 HV vs. LV) as
depicts Figure 2 (n=14 in all groups).
As well, histopathological studies revealed alterations in the high-stretched
animals. Figure 3 displays representative micrographs of n = 15 lungs examined in
both MV groups. Left micrograph corresponds to LV rats, which had no evidence of
morphological lung injury. In contrast, capillary congestion, alveolar type I cells
necrosis, and hyaline membrane formation covering the denuded epithelial surface
were presented in HV animals (Figure 3 [right]).
Figure 2: BAL cell counts in all experimental groups (all groups n=14).
The number of cells recovered in BAL was determined by cell viability with trypan
blue dye exclusion. Data are mean ± S.E.M. ** p< 0.001 vs. C; # p<0.05 vs. LV.
0,0
0,5
1,0
1,5
2,0
2,5
Nº
ce
ls x
106
HVLV
**
C
**
#
Number of BAL cells
115 Chapter 1
4.2.2. Total protein and carbonylated proteins in BAL
Total amount of proteins in the alveolar fluid as well as their oxidized state were
evaluated in BAL of n=8 and n=5 rats per group, respectively (Figure 4).
There was a significant increase in total protein presence in BAL in HV in
contrast with all groups (p<0.001). This result reflects an increase of protein in BAL
probably due to an increase of protein release in the alveolar space and alterations in
the alveolar-capillary barrier allowing leakage of plasma proteins into the alveolar
space.
As well, we observed in these rats an increase of carbonylated proteins in BAL of
the rats injuriously MV in contrast with Control group (p<0.01).
Figure 3: Histological micrographs of rats ventilated with Low or High tidal volumes
during 150 min (all groups n=15).
Representative light micrographs obtained from isolated left lungs of LVgroup (left) and
HV group (right) stained withhematoxylin-eosin.
LV HV
Lung tissue micrographs from MV groups
116 Chapter 1
4.2.3. Damage markers
We studied the presence of two damage markers in the alveolar space using n=5
animals per group: TNF-α and Acid Sphingomyelinase (ASMase) activity (Figure 5).
TNF-α is a pleiotropic cytokine with multiple functions in the inflammatory
response(331). This cytokine increased significantly in BAL of HV group (p<0.001),
while it was undetectable in plasma of both groups (Figure 5a).
On the other hand, ASMase catalyze the hydrolysis of sphingomyelin (SM) to
ceramide and coline phosphate, being ASMase-derived ceramide a promoter of
several pathways leading to ALI (332). We observed a significant increase of
ASMase activity in BAL of MV groups, being significantly higher in HV group
(Figure 5b). Interestingly, its levels in plasma did not vary between groups (data not
shown).
Figure 4: Total protein levels and its oxidized state in broncholalveolarlavage of
Control and ventilated rats with Low/High tidal volumes during 150 min.
Total amount of proteins (a, n=8) and protein oxidation content (b, n=5) were
assessed in BAL in all groups of study.
Data are mean ± S.E.M. **p< 0.01vs. Control and ***p< 0.001 vs. all groups.
BAL
0
5
10
100
150
200
mg p
rote
in in B
AL/ kg b
. w
t
Total protein
0
5
10
15
20
25
nm
ol D
NP
H/m
g p
rote
in in B
AL
Protein carbonilation
HVLV
***
C HVLVC
**
b)a)
117 Chapter 1
4.3. Surfactant analysis
4.3.1. Composition analysis
PS is comprised of 90% lipids, predominantly phospholipids (PL), and 10% of
proteins, mainly the PS-associated proteins: SP-A, SP-B, SP-C and SP-D. PS is
secreted as its functional fraction (LA) by ATII to the alveolar space. In a normal
lung, compression and expansion during respiration leads the conversion of LA to a
non-functional fraction (SA), are either degraded or recycled by alveolar macrophages
or ATII (314). Conversely, under pathological situations, there is an alteration of the
conversion of LA to SA, being the increase of the SA/LA ratio a damage marker of
VILI.
Figure 5: TNF-α and Acid Sphingomyelinase activity levelsin
broncholalveolarlavage of control and ventilated rats with Low/High tidal volumes
during 150 min.
a) TNF-αwas measured in BAL and plasma of all groups using a colorimetric rat
ELISA kit (n=5 per group). There were significant differences between HV and all
groups in BAL. Plasma levels were undetectable.
b) ASMase activity was measured in BAL and plasma of both ventilated groups
performing an enzymatic assay (n=5 per group).There were significant differences
between MV groups and Control group in BAL while there were no differences in
plasma among groups (data not shown).
Data are mean ± S.E.M. ** p<0.01vs. Control and *** p< 0.001 vs. all groups.
0
2
4
6
8
TNF-
HVLVC
***
TN
F-
ng/k
g b
w)
0
20
40
60
80
100
120
140
ASMase activity
HVLVC
***
nm
ol [1
4C
]P-c
holin
e/m
l/h
**
BAL
b)a)
118 Chapter 1
Therefore, we evaluate possible alterations in LA to SA conversion and their total
PL amounts in n=11 rats per group (Figure 6). Moreover, we studied PS-associated
protein levels in LA and its RNA expression in lung tissue of n=5 rats in all groups
(Figures 7, 8 and 9).
The content of total PL in PS significantly increased in High VT group (p<0.001).
This increase was primary due to a significant increase of PL in SA fraction (p<0.001)
while in LA did not differ among groups. Accordingly, SA/LA ratio was significantly
altered in those rats exposed to high VTMV (p<0.001). These data suggest that
injurious MV increases PS secretion but also alters its metabolism.
Figures 7, 8 and 9 represent RNA and protein levels of PS-associated proteins
analyzed in n=5 animals of all groups of study.
Figure 7 represents SP-A data. Immunoblotting reveals a significant decrease of
SP-A in HV groups in contrast with rest of groups (p<0.01). Additionally, we also
detected a significant decrease of SP-A RNA levels in HV group vs. Control
(p<0.05).
Figure 6: Total amount of phospholipids (PL) in pulmonary surfactant (PS) and PS
fractions of rats ventilated with Low/High tidal volumes during 150 min.
Total PL content in PS and the active (LA) and inactive (SA) fractions of PS were
measured in n=8 animals of both groups of study.As well, it was determined the ratio of
PL content between SA and LA in both groups. We observed significant differences in
HV group. Data represent mean ± S.E.M. ***p< 0.001 vs. all groups.
PS
0
2
4
6
8
10
m
ol P
L/ K
g b
ody
wt ***
HVLVC
LA
0
1
2
3
4
5
6
m
ol P
L/ K
g b
ody
wt
HVLVC
SA
HVLVC
***
SA/LA
0,0
0,5
1,0
1,5
2,0
PL r
atio
HVLVC
***
119 Chapter 1
On the other hand, Figure 8 depicts SP-B results. Interestingly, we detected a
significant decrease in HV group of both protein and RNA levels vs. Control whereas
we observed and increasing trend of SP-B protein levels in LV group together with a
significant increaseof its RNA levels in this group (p<0.01).
SP-C results showed in Figure 9, depicts a significant increase of protein levels in
LV group in contrast with the significant decrease observed in HV group. As well,
RT-PCR revealed a significant fold decrease of SP-C in HV group (p<0.001 vs. all
groups).
Figure 7: Presence of the collectin SP-A in large aggregates (left) and its RNA
expression in lung tissue (right) of n=5 rats ventilated with Low/High tidal volumes
during 150 min or non-ventilated (C).
Protein levels of SP-A were detected in LA by Western blot (WB) after 12% reducing
SDS/PAGE loading 1 µg of total protein and quantified by densitometric evaluation.
RNA expression of SP-A in lung tissue was assessed using total RNA isolated from the
lower lobe of the right lung. cDNA synthesis was performed using 1µg total RNA as input
and it was amplified by RT-PCR using specific primers.
Data represent mean ± S.E.M. * p<0.01 vs. C and ** p<0.01 vs. all groups.
WB band intensity
0
20
40
60
80
100
120
SP
-A (
% C
ontr
ol)
**
HVLVC
kDa
-
-
-
-
-
133
84
41
17
31
LV HVC
mRNA levels
0,0
0,5
1,0
1,5
2,0
SP
-A F
old
change
HVLVC
*
WB
SP-A
120 Chapter 1
Figure 8: Presence of the hydrophobic peptide SP-B in large aggregates (LA) and
their RNA expression in lung tissue of n=5 rats ventilated with Low/High tidal
volumes during 150 min or non-ventilated (C).
Protein levels of SP-B were detected by WB after 12% SDS/PAGE under non-reducing
conditions applying 5 nmol of total PL of LA (left) and quantified by densitometric
evaluation (center). RNA expression of SP-B was assessed by RT-PCR using specific
primers previous isolation of RNA from the lower lobe of the right lung. Results were
analyzed using ΔΔCT method and expressed as normalized fold expression (right).
Data represent mean ± S.E.M. * p<0.05 vs. Control and ** p<0.01 vs. all groups.
LV HVC kDa
-
-
-
-
-
133
84
41
17
31
- 7
-205
WB band intensity
0
20
40
60
80
100
120
140
SP
-B (
% C
ontr
ol)
**
HVLVC
mRNA levels
0,0
0,5
1,0
1,5
2,0
SP
-B F
old
change
HVLVC
*
**
WB
SP-B
LV HVCkDa
-
-
-
-
-
7
3
31
27
14
WB band intensity
0
20
40
60
80
100
120
140
160
SP
-C (
% C
ontr
ol)
***
HVLVC
*
mRNA levels
0,0
0,2
0,4
0,6
0,8
1,0
1,2
SP
-C F
old
change
HVLVC
***
WB
SP-C
Figure 9: Presence of the hydrophobic peptide SP-C in large aggregates (LA) and
their RNA expression in lung tissue of n=5 rats ventilated with Low/High tidal
volumes during 150 min or non-ventilated (C).
Protein levels of SP-C were detected by WB after 18% SDS/PAGE under non-reducing
conditions applying 3 nmol of total PL of LA (left) and quantified by densitometric
evaluation (center).RNA expression of SP-C was detected using total RNA isolated from
the lower lobe of the right lung. cDNA synthesis was performed using 1µg total RNA as
input and it was amplified by RT-PCR using specific primers. Results were analyzed
using ΔΔCT method and expressed as normalized fold expression (right).
Data represent mean ± S.E.M. * p<0.05 vs. Control and *** p<0.001 vs. all groups.
121 Chapter 1
4.3.2. Pulmonary surfactant functionality
PS biophysical function was determined measuring the ability of LA to adsorb
onto and spread at the air–water interface, by following the variation in surface
pressure as a function of time (322).
Figure 10 depicts PS interfacial adsorption of all groups of study (n=5 per group).
While Control and LV groups were near to the equilibrium pressure at 30 minutes,
HV group pressure was significantly lower at the same time, suggesting functional
impairment (p<0.001).
Figure 10: Pulmonary surfactant functionality of n=5 rats from all groups.
Surfactant function was determined measuring its ability to adsorb onto and spread
at an air-water interface. Surfactant interfacial adsorption in HV groups decreased
significantly compared with rest of groups (*** p< 0.001). Data are mean ± S.E.M.
Interfacial adsorption
Time
0 10 20 30
0
10
20
30
40
50
C
LV
HV
(
mN
/m)
***
122 Chapter 1
4.3.3. Presence of pulmonary surfactant inhibitors.
We studied several inhibitors of surfactant function previously described in other
animal models and in vitro studies (6, 322, 333). For example, protein leakage into
the alveolar space contributes to PS impairment due to the possible competition
between LA and surface-active plasmatic proteins for reaching the air-liquid interface
(6). According to this, we detected a significant contamination of proteins in the
active fraction of PS in the HV group (p<0.001), depicted as protein to PL ratio in LA
(Figure 11a, n=6 in both groups). Furthermore, we observed a significant increased in
HV group of C-reactive protein (CRP) levels (p<0.001), determined in 4 rats per
group as the percentage of CRP to PL in PS (Figure 11b). Previous studies in our
laboratory determined that CRP is an acute-phase protein that inhibits PS
functionality by binding to it when reaches the alveolar space (333). Therefore, this
data indicates that CRP is implicated in PS impairment in this model.
On the other hand, it is widely accepted that mechanical stress stimulates reactive
oxygen species (ROS) production (292) and some studies also demonstrated in vitro
that PS oxidation is intimately related with PS impairment (334). Hence, we observed
a significant increase of LA lipid peroxidation in HV group (p<0.05) as depicts Figure
11c (n=4 in both groups).
Figure 11: Presence of pulmonary surfactant inhibitors in all groups.
a) Total protein to PL ratio in LA was assessed in n=6 animals of all groups of study.
This ratio significantly increased in HV group.
b) CRP was measured using a rat CRP ELISA kit. CRP to total PL in PS ratio
significantly increased in HV group (n=4 per group).
c) Lipid hydroperoxides were quantified in lipid extracts of LA of n=4 samples by
FOX method. Lipid hydroperoxides significantly increased in LA of HV group.
Data represent mean ± S.E.M. *p<0.05 vs. Control and ***p<0.001 vs. all groups.
0
5
10
15
20
25
30
pm
ol H
P/n
mol P
L L
A
Lipid peroxidation
*
HVLVC
c)Protein/PL
0,0
0,2
0,4
0,6
0,8
Pro
t/P
L in L
A w
t ***
HVLVC
a) CRP/PL
0
1
2
3
4
% C
RP
/Tota
l P
L w
t
***
HVLVC
b)
123 Chapter 1
5. DISCUSSION
The present study allows linking the alterations detected in the alveolar space due
to VILI as well as highlights novel factors directly involved in PS alterations. This
model depicts that injurious MV disturbs simultaneously three levels in the alveolar
space: alveolar epithelium, alveolar fluid cells and PS.
Light micrographs from the injurious ventilated group showed alterations in the
alveolar space concerning epithelial disturbances such as alveolar type I cells necrosis
or thickening of the alveolar wall by hyaline membranes deposition. Also, we
observed a decrease of alveolar fluid cells in this group. As hyaline membranes are
composed by cellular debris and fibrin, our data suggest that the overinflation
produced by high VT and PEEP absence may induce alveolar cells necrosis
comprising part of hyaline membranes. However, we also observed a significant
decrease of alveolar fluid cells in LV group. As other groups have previously
suggested that MV may induce alveolar cells adhesion to the epithelium (273, 309),
we dare to speculate that MV may push alveolar cells to alveolar epithelium and
depending on the overinflation produced,might lead to cell death. Therefore, it is
reasonable to suggest that MV itself directly affects to alveolar cells by several
mechanisms depending on the strategy applied.
Interestingly, tissue injury is usually linked with alterations in the alveolar
capillary barrier (235). Accordingly, our data suggest similar alterations as we
observed an increase of total protein in BAL. However, an increase of damage
markers release in the alveolar space may contribute to this result.
In fact, we detected a significant increase of two damage markers in the alveolar
space of HV group.
Sphingomyelinases are enzymes that catalyze the hydrolysis of sphingomyelin to
ceramide and coline phosphate (335). Specifically, ASMase plays a key role in the
SM/ceramide-signaling pathway, important for its implication in the pathogenesis of
ALI (332). Several in vivo studies reported an increase of ASMase activity in lungs
and serum (336, 337), and the lack of its presence showed an attenuation of
inflammation (337) and edema (336) in ALI. Here we observed an increase of
ASMase activity in BAL of MV groups, being its presence higher in high-ventilated
animals. These data suggest that MV may induce the increment of ASMase activity in
the alveolar space considering edema as a possible source in the case of HV group.
124 Chapter 1
Additionally, we observed an increase of TNF-α exclusively in the alveolar
compartment. Even though several models of VILI reported no changes in TNF-α
levels in BAL (257, 294), many other VILI models including ours found an increment
of this acute-phase cytokine in the alveolar space (250, 296).
However, an interesting role of this early acute inducible cytokine is its
involvement in the production of reactive oxygen species (ROS) by various cell types
(331, 338). It is known that patients with ARDS are subjected to an increase
generation of ROS and reactive nitrogen species (RNS) produced by alveolar cells
after proinflammatory stimulation, altering the endothelial barrier function and thus
increasing its permeability (339, 340). Furthermore, stimulation of ROS production in
response to elevated mechanical stretch has been mainly detected in endothelial cells,
but also in epithelial cells, macrophages or fibroblasts, being widely accepted that
they may contribute to the onset of VILI (290-292). However, sources and pathways
leading to this production are still under discussion (290). Besides, we observed an
increase in carbonyl proteins in BAL fluid together with lipid peroxidation increment
in LA of high-stretched rats, suggesting that alveolar space is under oxidative stress.
It has been previously reported increments of carbonyl proteins in lung tissue
(341) and malondialdehyde contents in the epithelial lining fluid (342) under MV as
well as several studies confirm a relationship between PS biophysical activity
impairment and its oxidation by different mechanisms (334). However, detection of
LA peroxidation in a VILI in vivo model is a novelty and directly contributes to the
PS impairment observed.
Conversely, we observed a significant increase of PS release in the alveolar space
in those rats highly stretched. Interestingly, we only detected a significant increase of
SA meanwhile LA remained stable, together with an increment of the SA/LA ratio.
These findings are consistent with similar results previously obtained applying high
VT and no PEEP during 1h (294, 296, 297), being suggested that the increment of the
SA/LA ratio due to the alteration of the LA to SA conversion is a damage marker in
VILI (298). These data suggest that injurious MV induced PS release into the alveolar
space but fresh PS may be rapidly altered by several damage markers in the alveolar
space as depicts the increment of LA to SA conversion.
Together with LA peroxidation, we observed a significant increase of protein
contamination in this fraction that may contribute to both functional impairment and
alteration in LA to SA conversion. In fact, it is widely accepted that vascular leakage
125 Chapter 1
of proteins into the alveolar space contributes to PS biophysical activity dysfunction
(329). The increment of total protein to PL ratio in LA suggests a possible
competition between LA and some surface-active plasmatic proteins such as albumin
or fibrinogen, which has been shown to compete for reaching the air-liquid interface
(6).
However, we studied CRP, an acute-phase protein that directly binds to PS
inhibiting its biophysical function (322, 333). CRP is produced in humans and other
animal species primarily by hepatocytes after inflammation or infection and secreted
to the serum (343, 344). Besides, alveolar ATII and macrophages stimulated by pro-
inflammatory mediators are also able to produce it (345-347). Previous studies in our
laboratory detected elevated levels of CRP in BAL and plasma in patients with
ischemia-reperfusion injury and studied the effect of CRP in PS functionality in vivo
and in vitro (322, 333). In this study, we detected a significant increase of the
percentage of CRP to total PL of PS ratio in injurious MV rats. Consequently, this
study demonstrates for the first time the implication of CRP in the pathogenesis of
VILI. In addition, previous studies in our group observed an increase in CRP
associated with a decrease in SP-A under lung injury. This SP-A deficiency is critical
because our laboratory demonstrated previously in vitro that SP-A binds to CRP,
inhibiting its adverse effect (322, 333).
Accordingly, we observed a significant decrease of protein and RNA levels of
SP-A in rats injuriously ventilated. The hydrophilic collectin SP-A is involved in
several functions in the alveolar space such as lung defense or PS homeostasis.
Specifically, SP-A contributes to LA maintenance, protects PS against inactivation by
binding blockade and enhances PS adsorption (55). Hence, these data suggest that SP-
A deficiency is also critical in VILI, as it cannot accomplish its protective and
homeostatic role appropriately.
Moreover, we observed a decrement of protein and RNA levels of the
hydrophobic peptides SP-B and SP-C, being both essential in PS adsorption and
surface tension reduction (55). Interestingly, these protein decrease has been observed
in several clinical studies of ARDS patients (5, 61, 348) as well as some VILI models
revealed a decrease of SP-B and SP-C RNA levels (295) and SP-B protein levels
(296).
However, it is the first time, as far as we know, that is detected a decrease of
both, RNA and protein levels, of SP-A, SP-B and SP-C in VILI. Hence, these data
126 Chapter 1
suggest that high-stretch MV altersPS-associated proteins production by ATII, being
their lack a direct contributor of PS functionality impairment. A plausible explanation
for the altered pattern of PS-associated proteins expression could be an increase of
modulator factors in the alveolar space, such as proinflammatory mediators, leading
to ATII alterations. For example, previous studies indicate a relation between
increased TNF-α concentrations and a decreased of RNA levels of SP-B and SP-C
(295). Nevertheless, degradation of these proteins in the alveolar space might be
another contributor of their lack.
To summarize, injurious MV instigates the release of inflammatory factors by
alveolar epithelial and fluid cells as well as promote protein contamination due to the
alteration of the alveolar-capillary barrier. These features are involved in signaling
pathways that exacerbate the existing damage, being an important target PS.
As a result, the presence of damage markers in the alveolar space directly affects
PS functionality by oxidizing its functional fraction or due to protein binding that
directly inhibits its function. As well, PS composition is altered, probably caused by
ATII alterations, directly affecting its functionality due to decrease of PS-associated
proteins. Moreover, ATII and alveolar cells alterations are involved in LA to SA
conversion and reuptake. Consequently alteration of PS metabolism and functionality,
in turn triggers an increase of alveolar infiltrations by altering the equilibrium
pressures between the alveoli and the capillaries, generating a damaging feedback
leading to atelectasis and impairment of gas exchange.
Therefore, this study allows interrelating many of the factors directly involved in
acute lung injury that also contributes to pulmonary surfactant impairment.
Chapter 2 127
Chapter 2
Factors involved in the
resistance to ventilator-
induced lung injury
Chapter 2 128
Chapter 2 129
1. ABSTRACT
Ventilator-induced lung injury is a pulmonary damage caused by injurious
mechanical ventilation that besides having a wide range of known alveolar alterations
it also has a heterogeneous outcome.
The aim of the present study was to elucidate the possible different responses to
the application of the same injurious high-stretch ventilation, trying to identify factors
involved in the resistance to ventilator-induced lung injury.
Sprague-Dawley rats were randomly distributed in the following groups: Control
(n=5), low-stretch ventilation (LV) (VT = 9 ml/kg, PEEP = 5 cm H2O) (n=5) or high-
stretch ventilation (HV) (VT = 25 ml/kg, PEEP = 0cm H2O) (n=17). HV group was
subdivided in two groups: 1) animals greatly susceptible to HV (sHV), showing a
substantial PaO2/FiO2 reduction at 60 min of ventilation; and 2) animals resistant to
HV (rHV), with insignificant changes inPaO2/FiO2 at 60 min. Lung tissue, plasma,
bronchoalveolar fluid (BAL), BAL cells and lung surfactant were analyzed in all
groups.
Injurious high-stretch ventilation induced a vulnerable and a resistant response.
The vulnerable group was characterized by hyaline membranes formation,
pronounced decrease of alveolar macrophages, intra-alveolar edema, inflammatory
markers in BAL (TNF-α, MIP-2, MCP-1 and acid sphingomyelinase activity) and
alterations in the composition and biophysical activity of lung surfactant, which
contained significant levels of peroxides. In contrast, the resistant group was
distinguished by an attenuate lung inflammatory response (characterized by IL-6
increase), high amounts of fully active surfactant, absence of edema and normal
physiological parameters after 150 min of HV.
These findings suggest that an attenuate inflammatory response together with
increased release of active surfactant into the alveolar space prevent edema and a
worsened response to high-stretch ventilation.
Chapter 2 130
2. INTRODUCTION
Acute lung injury (ALI) and its severe form, acute respiratory distress
syndrome (ARDS), are the major acute respiratory failures with an elevated incidence
in critical care units (175). However, the determination of their incidence has been
complicated to assess due to their etiologic variability. These syndromes are closely
related with insults that directly or indirectly affects to the lungs (e.g. pneumonia,
sepsis, respectively.), contributing to their heterogeneity outcome (173). Furthermore,
some studies suggest age and race as other factors involved in mortality risk (173,
175). Despite this, mortality rates have decreased significantly in the last decade (47,
173).
The main factor involved in this mortality reduction is the improvement of
protective ventilation strategies, the only effective treatment to date (173). However,
these studies also highlighted ventilator strategies that worsening the existing damage
or even initiate it. Therefore, knowing the alterations attributable to mechanical
ventilation (MV) has an essential clinical relevance that led to develop several clinical
trials and establish numerous animal models to characterize it.
Clinical studies concluded that even applying the same stress to the lungs of
different patients, forces that reach to their cells and the corresponding response are
quite heterogeneous and variable (299), presuming that personalizing ventilator
strategies according to the particular patient injury status will improve their outcome
(349).
On the other hand, several experimental models have been performed in order to
elucidate the main features attributable to MV. As a result, many groups studied
inflammatory responses under different stretching stimuli (238, 293). Also some
studies were aimed at discovering mechanisms leading to vascular permeability (236,
327, 336), detecting physiological variables alterations (328) or examining pulmonary
surfactant alterations due to MV (294-298, 330). However, few studies addressed a
global study in a single model in vivo (Chapter 1). Consequently, the experimental
design variability and the variation of factors influencing this injury, lead to a wide
range of biologic outcomes that limited a consensus on the importance of the factors
determined and their link to systemic dysfunction (256, 350).
Nonetheless, some studies attribute these heterogeneity outcomes to different
degrees of susceptibility to mechanical stress, arguing that a failure in the activation
Chapter 2 131
of protective mechanisms or their inhibition may lead to a damaging imbalance (299,
351, 352).
On the basis of the above information, we formulate the following questions:
Experimental animals facing the same injurious mechanical stress may develop
different responses according to their susceptibility?
If they do so, which are the main factors contributing to these different responses
to damage? Some of these factors could be useful to develop therapeutic strategies?
To address these questions we established a model of injurious MV which was
subdivided in two groups according to variations in mean arterial pressure (MAP) at
60 min. Subsequently, we investigate the possible different responses to injurious MV
at different levels: physiological, histological, cellular, molecular and biochemical,
focusing especially on pulmonary surfactant.
3. EXPERIMENTAL DESIGN
Male Sprague-Dawley rats were anesthetized and a surgical tracheotomy was
performed to ventilate them. Subsequently, animals were randomly distributed in the
following groups:
Control group (C) (n=5): animals undergoing identical anesthetic and surgical
procedures than the other groups but without applying MV.
Low-stretch ventilation group (LV) (n=5): rats were ventilated applying this
protective parameters: Tidal volume (VT) = 9 ml/kg, positive end-expiratory
pressure (PEEP) = 5 cmH2O, during 150 min.
High-stretch ventilation group (HV) (n=17): animals were ventilated under
damaging conditions: VT = 25 ml/kg, PEEP = 0 cm H2O, during 150 min.
In both ventilated groups, respiratory rate was 70 bpm, inspiratory time 0.35
sec., expiratory time 0.56 sec. and FiO2 0.35. Animals were ventilated for an
equilibration period of 30 min using the low VT ventilation parameters. Then, the
assigned VT was administered starting at t=0 min up to 150 min.
Ventilatory and hemodynamic parameters of ventilated groups were registered
and controlled during the ventilatory process. HV group was subdivided according to
the variations in MAP at one hour:
Chapter 2 132
Animals resistant to HV (rHV) (n=6): animals with no changes in MAP at 60
min, sacrificed at 150 min.
Animals susceptible to HV (sHV) (n=11): animals with a significant MAP
reduction at 60 min and sacrificed at this point (MAP≤50 mmHg).
Hemodynamic and ventilatory parameters were registered at t=0 min, t=60 min
and t=150 min. Blood samples were drawn before and after the ventilatory procedure
for blood gases determination and its biochemical analysis.
At the end of the ventilatory period, the animals were sacrificed by
exsanguination and subsequently we proceeded to obtain bronchoalveolar lavage free
of cells (BAL), alveolar fluid cells and lung tissue.
Experimental design
Control (C): non-ventilated rats; n=5.
Settling time
30 min
t: 0 min t: 150 minLV
n=5
t: 0 min t: 60 min
HV
n=17 Settling time
30 min
VT=9 ml/kg, 5 cmH2O PEEP
VT = 25 ml/kg, 0 PEEP
Check
point
sHV: MAP ≤ 50 mmHg
n= 11 sacrificed at 60 min
t: 150 min
rHV: no changes in MAP
n= 6 sacrificed at 150 min
Figure 1: Experimental design. Representation of all groups established subdivided
according to the mechanical ventilation strategies.
Chapter 2 133
4. RESULTS
4.1. Physiology
We measured hemodinamic and ventilatory parameters in five rats per ventilated
group. Peak inspiratory pressure (PIP) and mean arterial pressure (MAP) were
analyzed at t=0 min, t=60 min and t=150 min of the ventilation period. As a result,
significant changes in MAP resulted in the subdivision of HV group according to this
criterion: MAP≤50 mmHg (Figure 2a). Interestingly, PIP already increased
significantly at the beginning of HV in sHV group (p<0.01 vs. rHV) and kept growing
during the following hour (p<0.001 vs. rHV), suggesting that PIP may be a good early
damage marker in the prediction of VILI (Figure 3). We also detected a severe
hypoxemia at the end of the ventilator period of sHV in contrast with rHV (p<0.01) as
depicted PaO2/FiO2 ratio in Figure 2b.
Figure 2: Changes during the mechanical ventilation (MV) period in hemodynamic
variables in n=5 rats from ventilated groups with Low or High tidal volumes.
a) Mean arterial pressure (MAP) was measured at baseline, start and after 1 and 2.5 hours of
MV. b) Arterial partial pressure of oxygen (PaO2)-to-fractional inspired oxygen (FiO2) ratio
values were assessed before and after MV.
Data represent mean ± S.E.M of n=5 rats per group. *p<0.001 vs. rHV.
MAP
Basal
0
20
40
60
80
100
120
140LV
rHV
sHV
0 h 1 h 2.5 h
Mechanical ventilation time
*mm
Hg
PaO2/FiO
2
Basal
0
200
400
600
LV
rHV
sHV
Post MV
*
PaO
2/F
iO2 (m
m H
g)
a) b)
Chapter 2 134
We also measured pH and lactate concentration in arterial blood at the end of
MV. Rats from sHV group presented systemic acidosis and hyperlactatemia in
contrast with both LV and rHV in the same time frame (Table 1). Furthermore, we
determined the levels of glucose, creatinine, lactate aminotrasferase (LDH) and
creatinine kinase (CK) enzymes in blood harvested at the end of MV. There was a
significant increase of glucose and LDH in sHV group vs. LV and rHV groups. Also
CK significantly increased vs. LV group (Table 1). Our data suggest an increase of
anaerobic metabolism in sHV group.
PIP
Basal
cm
H2O
0
10
20
30
40 LV
rHV
sHV
0 h 1 h 2.5 h
Mechanical ventilation time
**
*
Figure 3: Changes during the mechanical ventilation (MV) period in peak inspiratory
pressure (PIP) in n=5 rats from ventilated groups with Low or High tidal volumes.
PIP was measured at baseline, start and after 1 and 2.5 hours of MV. Data represent mean ±
S.E.M of n=5 rats per group. *p<0.01 and **p<0.001 vs. rHV.
Chapter 2 135
4.2. Alveolar injury
Changes in the alveolar space due to MV were characterized by the evaluation of
histological score, alveolar fluid cells alterations and damage markers presence.
4.2.1. Alterations in the alveolar space
Histological score was evaluated in 5 animals per group and revealed alterations
in high-stretched animals, being significant in sHV group (p<0.05) (Figure 4a).
Interestingly, edema presence, represented as total amount of proteins in BAL
determined in 5 animals per group, only appeared in sHV group (p<0.001) (Figure
4b).
Parameter LV rHV sHV
pH 7.27±0.01 7.28±0.02 7.18±0.02* ###
Lactate (mmol/L) 0.73±0.13 0.87±0.08 2.85±0.39*** ###
Glucose (mg/dL) 121.8±6.73 147.85±10.47 253.5±20.64*** ###
Creatinine (mg/dL) 0.76±0.08 0.57±0.04 0.75±0.06
LDH (IU/L) 366.4±101.8 502.83±61.64 876.83±119.38* #
CK (IU/L) 317.2±33.78 756.3±176.3 1423.67±386.72*
Table 1: Changes in pH, blood enzymes and blood metabolites in rats subjected to Low (LV) or
High mechanical ventilation strategies during 60 (sHV) or 150 min (rHV).
Definition of abbreviation: LDH: lactate aminotrasferase; CK: creatinine kinase.
All factors were measured at the end of the ventilator period. Data are mean ± S.E.M. *p<0.05,
**p<0.01, ***p<0.001, vs. LV; #p<0.05, ##p<0.01, ###p<0.001, vs. rHV.
Chapter 2 136
4.2.2. Alveolar fluid cells
Total cell counts in BAL were assessed in five animals of all groups.
Interestingly, alveolar cell counts decreased when MV was applied. In particular, cell
counts significantly decreased in the rHV (p<0.05) and sHV (p<0.001) groups (Figure
5a, left panel). Also, macrophages proportion significantly decreased in rHV (p<0.05)
and sHV (p<0.001) groups (Figure 4a, right panel). Hence, MV may change alveolar
fluid cells profile as depict the representative flow cytometric side scatter (SSC,
relative complexity)/forward scatter (FSC, relative size) dot plots from all
experimental groups (Figure 5b).
Figure 4: Alveolar injury in the different experimental groups.
Histological score was assessed by hematoxylin-eosin staining of the isolated and fixated left
lungs of n=5 animals of all groups. Edema presence was measured as total protein content of
bronchoalveolar fluid in n=5 animal per group.
Data represent mean ± S.E.M. *p<0.05, ***p<0.001 vs. Control.
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
Total protein in BAL
0
50
100
150
mg p
rot. in B
AL/ kg b
.wt
***
LV rHV sHVC
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
Histological score
0
10
20
30
40
50
*
His
tolo
gic
al score
LV rHV sHVC
a) b)
Chapter 2 137
Control LV
rHV sHV
Representative SSC/FSC scatterplotsb)
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
BAL cell counts
0,0
5,0e+5
1,0e+6
1,5e+6
2,0e+6
2,5e+6
Nº
cells
x10
6
*
***
LV rHV sHVC
a)
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
Macrophages
0
20
40
60
80
100
% m
acro
ph
ag
es in
BA
L
*
###
***
LV rHV sHVC
Figure 5: Alveolar cells profile in all experimental groups (n=5).
a) Left panel represent total cell counts recovered in BALdetermined by assessing cell
viability with trypan blue dye exclusion. Right panel depicted the proportion of alveolar
macrophages in BAL fluid determined by fluorescence flow cytometry using a specific
monoclonal antibodies anti-CD11c for alveolar. n=5 animal per group were analyzed.
Data represent mean ± S.E.M. *p<0.05, ***p<0.001 vs. Control; ###
p<0.001 vs. rHV.
b) Representative side scatter (SSC)/forward scatter (FSC) dot plots of the flow cytometric
profile of total alveolar fluid cells from all groups of study.
.
Chapter 2 138
4.2.3. Damage markers
The presence of cytokines (n=4) and chemokines (n=5) was determined in BAL
(Figure 6a and 6b) and plasma (Table 2) as well as the presence of acid
sphingomyelinase (ASMase) activity in these fluids (n=3) (Figure 6c and table 2).
IL-6 is a pleiotropic cytokine with multiple functions in the inflammatory
response (353). This cytokine only increased significantly in rHV group (p<0.05)
while its levels in plasma did not change among groups. Another pleiotropic cytokine
involved in acute inflammatory responses, TNF-α (331), also increased its levels in
the HV groups, being significant in sHV vs. Control (p<0.001), while it was
undetectable in plasma of all groups of study.
We also studied the presence of chemokines MCP-1 and MIP-2. MCP-1 is a
chemokine involved in proinflammatory responses, recruitment of monocytes and
memory T cells as well as a contributor of macrophages activation (354, 355).
Interestingly, MCP-1 significantly increased in BAL sHV (p<0.001 vs. Control and
p<0.05 vs. rHV). On the other hand, MIP-2 is a well-known neutrophil
chemoattractant involved in the elicitation of pulmonary neutrophilia (356), which
was significantly increased in rHV (p<0.05) and sHV (p<0.001 vs. Control and
p<0.05 vs. rHV) groups in BAL and also was significantly increased in plasma of
sHV (p<0.05).
In order to assess the possible modulatory role of IL-6, we determined a ratio
between each cytokine evaluated in BAL (TNF-α, MCP-1 and MIP-2) and IL-6. As a
result, we observe in Table 2 a significant increase of these ratios in sHV group in
contrast with control group values.
These data suggest that there are different inflammatory responses between HV
groups being exacerbated in sHV group.
ASMase catalyze the hydrolysis of sphingomyelin (SM) to ceramide and coline
phosphate, being ASMase-derived ceramide a promoter of several pathways leading
to ALI (332). ASMase activity significantly increases in BAL of sHV group (p<0.05)
compared with all groups whereas its levels in plasma did not vary among groups
(Table 2).
Chapter 2 139
Figure 6: Damage markers detected in BAL of all groups.
a) Inflammatory cytokines IL-6 and TNF-were measured in BAL of n=4 rats per group by
colorimetric rat ELISA kits. TNF-α levels increase in High VT groups and significantly in
sHV while IL-6 levels augment in High VT groups and significantly in rHV.
b) Inflammatory chemokines MCP-1 and MIP-2 were both detected by ELISA kits in BAL
on five rats per group. MCP-1 levels significantly increases in BAL of sHV group and MIP-2
significantly increases in both high-ventilated groups.
c) ASMase activity in BAL was measured by performing an enzymatic assay (n=3). ASMase
activity values in BAL increase in sHV vs. all groups.
Data represent mean ± S.E.M. *p<0.05, **p<0.01, ***p<0.001 vs. Control; #p<0.05 vs. rHV.
IL-6
0
25
50
75
100
125
150
**
*
pg IL-6
/ml B
AL
LV rHV sHVC
TNF-
0
5
10
15
20
***
pg T
NF
- /m
l B
AL
LV rHV sHVC
a)
MIP-2
0
50
100
150
200
250
300
350#
***pg M
IP-2
/ml B
AL
*
LV rHV sHVC
MCP-1
0
50
100
150
200
250 #
***
pg M
CP
-1/m
l B
AL
LV rHV sHVC
b)
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
ASMase activity
0
50
100
150
200
#*
nm
ol/m
l B
AL/h
LV rHV sHVC
c)
Chapter 2 140
4.3. Surfactant analysis
4.3.1. Pulmonary surfactant composition analysis
Pulmonary surfactant is a surface-active lipoprotein complex mainly composed
by 90% lipids, most of them PL but also a small proportion of neutral lipids and
cholesterol, and 10% of proteins being four the PS-associated proteins: SP-A, SP-B,
SP-C and SP-D. PS is secreted by ATII as large aggregates (LA), which accomplish
its main function. In a normal lung, compression and expansion during respiration
leads the conversion of LA to a non-functional fraction, the small aggregates (SA),
which are either degraded or recycled by alveolar macrophages or ATII (314).
Conversely, under pathological situations, there is an alteration of the conversion of
LA to SA, being the increase of the SA/LA ratio a damage marker of VILI.
Therefore, we evaluate possible alterations in total PL amounts in PS and its
fractions (Figure 7). Also we assess PS-associated protein levels and its RNA
expression in lung tissue (Figure 8).
The content of PL in PS is significantly increased in both high MV groups.
However, rHV group had LA significantly increased compared with all groups
(p<0.001) whereas sHV had significantly increased SA (p<0.001) as well as its
SA/LA ratio (p<0.001) in contrast with all groups. Therefore, high MV may induce
PS release into the alveolar space but in sHV is rapidly conversed to non-functional
aggregates.
Table 2: Relative content of cytokines referred to IL-6 levels in BAL and damage markers in plasma
of Control (C) and rats subjected to Low (LV) or High mechanical ventilation strategies during 60
(sHV) or 150 min (rHV).
Groups
BAL Plasma
TNF-α/IL-6 MIP-2/IL-6 MCP-1/IL-6 IL-6
(pg/ml)
MIP-2
(pg/ml)
ASMase activity
(nmol/ml/h)
C 7.1e-3
±4.9e-3
0.3±0.11 0.55±0.17 29.12±6 10.04±1.58 170.9±11.9
LV 0.03±0.017 0.8±0.2 0.49±0.1 40.5±2.3 8.1±2.1 178.3±13.5
rHV 0.066±0.03 1.1±0.3 0.95±0.15 42.3±1.5 13.65±1.82 161.7±15.3
sHV 0.16±0.04**
2.9±0.45***
2.25±0.35***
48.4±7.25 35.2±14.7* 152.6±15.3
Definition of abbreviation: TNF-α: Tumor necrosis factor alpha; IL-6: Interleukin 6; MIP-2: macrophage
inflammatory protein 2; MCP-1: monocyte chemotactic protein 1; ASMase: Acid sphingomyelinase.
All factors were measured at the end of the ventilator period. Data are mean ± S.E.M.* p<0.05 and
**p<0.01 vs. Control; *** p<0.001 vs. all groups.
Chapter 2 141
PS
m
ol P
L/ kg b
.wt
0
2
4
6
8
10
12
***
**
LV rHV sHVC
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
LA
***
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
SA
###
***
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
SA/LA
PL r
atio
0,0
0,5
1,0
1,5
2,0
2,5###
***
LV rHV sHVC LV rHV sHVC LV rHVC sHV
Figure 8 shows protein and RNA levels of the specific surfactant proteins SP-A,
SP-B and SP-C of all MV groups.
Immunoblotting reveals a significant decrease of SP-A (p<0.05 vs. rHV) and SP-
B (p<0.001 vs. rHV and p<0.01 vs. LV) levels in sHV group analyzing four animals
per ventilator group. SP-C protein levels were analyzed in two animals per ventilator
group. The results depicted significant decrease of SP-C levels in HV groups
(p<0.001 vs. LV), obtaining significant differences between them (p<0.05).
As well, RNA levels were evaluated in four animals per HV group and two
animals in LV group. As a result, we detected a significant fold decrease of the RNA
levels of the three PS-associated proteins evaluated in both HV groups in contrast
with LV.
Figure 7: Total amount of phospholipids (PL) in pulmonary surfactant (PS)and its
fractions of all experimental groups (n=5).
Total PL content in PS and its active (LA) and inactive (SA) fractions were measured in all
groups of study. As well, it was determined the ratio of PL content between SA and LA.
There was a significant increase of PS in high-stretched groups. Interestingly, there was a
significant increase of the LA amounts in rHV whereas sHV had a significant increase in
SA and SA/LA ratio.
Data represent mean ± S.E.M. ** p<0.01 and ***p<0.001 vs. Control; ###
p<0.001 vs. rHV.
Chapter 2 142
Figure 8: Presence of specific surfactant proteins SP-A, SP-B and SP-C in large
aggregates (LA) and its RNA expression in lung tissue of all ventilated groups.
Protein levels were detected in LA samples by Western blot. Proteins quantification was
achieved by densitometric evaluation (n=4 per group in SP-A and SP-B; n=2 per group in
SPC).
RNA expression of SP-A, SP-B and SP-C was detected using total RNA isolated from the
lower lobe of the right lung. cDNA synthesis was performed using 1µg total RNA as input
and it was amplified by RT-PCR using specific primers. Results were analyzed using ΔΔCT
method and expressed as normalized fold expression. (n=4 per HV group and n=2 in LV
group).
Data represent mean ± S.E.M. **p<0.01 and***p<0.001 vs. LV; #p<0.05 and
###p<0.001
vs.rHV.
0
20
40
60
80
100
120
140
SP
-B %
(LV
)
**###
SP-A
SP-B
SP-C
WB band intensity
0
50
100
150
200
SP
-A %
(LV
)
#
0
20
40
60
80
100
SP
-C %
(Contr
ol)
LV rHV sHV
***
**
#
0,00
0,25
0,50
0,75
1,00
1,25
SP
-C F
old
ch
ang
e
***
LV rHV sHV
***
0,0
0,2
0,4
0,6
0,8
1,0
1,2
SP
-B F
old
change
***
#
***
mRNA levels
0,0
0,2
0,4
0,6
0,8
1,0
1,2
SP
-A F
old
change
***
**
Chapter 2 143
4.3.2. Pulmonary surfactant functionality
Pulmonary surfactant biophysical function was determined using to techniques:
Interfacial adsorption assay and Captive Bubble Surfactometry.
4.3.2.1. Interfacial adsorption
The ability of LA to adsorb onto and spread at the air–water interface was
measuredin four rats per experimental group using a Wilhelmy-like high-sensitive
surface microbalance, coupled to a teflon dish of very small size by following the
variation in surface pressure as a function of time, as previously described (322). This
ability has been significantly impaired in sHVgroup at 30 min in contrast with all
groups (p<0.001), as shows Figure 9.
Figure 9: Interfacial adsorption of the active fraction of pulmonary surfactant of all
experimental groups (n=4).
Surfactant interfacial adsorption was determined in a Wilhelmy-like high-sensitive surface
microbalance. Surfactant interfacial adsorption of sHV is significantly altered.
Data represent mean ± S.E.M. ***p<0.001 vs. all groups, by one-way ANOVA using a
Bonferroni pos hoc test when appropriate.
Interfacial Adsorption
Time (min)
0 10 20 30
0
10
20
30
40
50
C
LV
rHV
sHV
mN
/m)
***
Chapter 2 144
4.3.2.2. Captive Bubble Surfactometry
This is the best technique to simulate the compression-expansion cycling that
happens at the breathing interface in order to evaluate the three main characteristic
dynamic properties of PS: very rapid interfacial adsorption (~23 mN/m), low surface
tension upon compression (less than 2mN/m) and efficient re-extension upon
expansion (325, 357, 358). Figure 10 compares interfacial adsorption kinetics of 20
mg/ml of LA of three rats from HV groups and Control group assessed after
deposition at the interface of the captive air bubble in the captive bubble
surfactometer. Control group adsorbs to form a stable surface film with a minimum
equilibrium surface tension of ~23 mN/m within the first seconds after deposition.
rHV also reached this surface tension but it takes more time. However, sHV LA was
far from reaching the equilibrium tension (41.6 ± 0.7 mN/m; p<0.001 vs. all groups)
(Table 3). Also, re-adsorption of excess material upon expansion of the bubble (see
the lower panel in figure 10) had the same pattern in all groups than in initial
adsorption measurements, being significantly increased the equilibrium tension of
sHV LA (p<0.001 vs. all groups) (Table 3).
Cycling isotherms acquired from LA of three rats from Control and rHV rats did
not represent any compression/expansion hysteresis along dynamic cycles (Figure
11). Only the first dynamic cycle of rHV group exhibited hysteresis presence, which
was lost in the subsequent cycles. All isotherms reached surface tensions ~4mN/m
with <15% compression. In contrast, isotherms of sHV LA (n=3) depicted a marginal
hysteresis as well as maximal and minimal surface tensions significantly higher than
the other groups associated with 30% compression (Figure 11 and Table 4).
Chapter 2 145
Figure 10: Initial and post-expansion adsorption of the active fraction (LA) of
pulmonary surfactant from n=3 animals of Control and high-ventilated groups
evaluated in captive bubble surfactometer.
Upper panels are representative samples of initial adsorption (top) immediately after the
application of 20 mg/ml of LA into the bubble‟s air-liquid interface and post-expansion
adsorption (below) of all samples. As well, media values of the minimum surface tension (γi)
reached at 5 min after sample application and media values of the minimum surface tension
(γpost) reached at 5 min after interface expansion are represented (lower panels).
Data represent mean ± S.E.M. ***p<0.001 vs. all groups.
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
Initial
(m
N/m
)
0
20
40
60
rHV sHVC
***
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
Post-expansion (
mN
/m)
0
20
40
60
rHV sHVC
***
Control
(m
N/m
)
0
20
40
60 Initial
0 50 100 150 200 250 300 350
(m
N/m
)
0
20
40
60
rHV
Time (s)
0 50 100 150 200 250 300 350
sHV
0 50 100 150 200 250 300 350
Post-expansion
Adsorption CBS
Table 3: Initial adsorption and post-expansion adsorption of
pulmonary surfactant from control rats and rats injuriously ventilated
during 60 (sHV) or 150 min (rHV) assessed in a captive bubble
surfactometer.
Groups Interfacial adsorption
γmin (mN/m) t=5 min
Post-expansion adsorption
γmin (mN/m) t=5 min
C 22.7±1.4 22.4±0.4
rHV 23.6±0.8 23.8±0.4
sHV 41.6±0.7***
45.1±1.2***
Definition of abbreviation: γmin: minimum surface tension.
Data are mean ± S.E.M. ***
p<0.001 vs. all groups.
Chapter 2 146
Figure 11: Dynamic compression-expansion isotherms of the active fraction (LA) of
pulmonary surfactant fromn=3 animals of Control and high-stretched groups evaluated
in captive bubble surfactometer.
Upper panels are representative surface tension/relative area isotherms obtained from 1º, 10º
and 20º cycles during the dynamic cycling process of 20 cycles/min. Lower panels depict
media values of minimum (γmin) and maximum (γmax) surface tensions as well as compressed
area values at γmin (ACγmin) registered during the first and last cycle from dynamic processes.
Data represent mean ± S.E.M. **p<0.01, ***p<0.001 vs. Control; ###
p<0.001 vs. rHV.
Table 4: Effect of injurious mechanical ventilation during 60 (sHV) or 150 min (rHV)
on the active fraction of pulmonary surfactant surface activity assessed in a captive
bubble surfactometer under dynamic conditions.
Definition of abbreviation: γmin: minimum surface tension; ACγmin: relative area of
compression at minimum surface tension; γmax: maximum surface tension.
Data are mean ± S.E.M. **
p<0.01 and ***
p<0.001 vs. Control; ###
p<0.001 vs. rHV.
Groups
Dynamic Cycles
Cycle 1 Cycle 20
γmin (mN/m) ACγmin (%) γmax (mN/m) γmin (mN/m) ACγmin (%) γmax (mN/m)
C 4±1.2 16.1±3.8 24.1±0.5 2.9±0.2 12.3±1.6 29.5±1.6
rHV 8±2 26±4 24.3±0.6 3.5±0.1 13±0.6 30.7±0.6
sHV 21.2±0.2***### 34.3±1.7** 48.6±1.4***### 21.2±0.2***### 34.6±1.5***### 56.2±0.8***###
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
0
20
40
60
Cycle 1
Cycle 20
C rHV sHV
***###
max(m
N/m
)
***###
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
0
20
40
60
Cycle 1
Cycle 20
C rHV sHV
***###
min(m
N/m
)
***###
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
0
20
40
60
80
100
ACmin cycle 1
ACmin cycle 20
C rHV sHV
AC m
in (
cm
2)
** ***###
% CompressionMinimum surface
tension
Equilibrium surface
tension
0,0 0,2 0,4 0,6 0,8 1,0
(m
N/m
)
0
20
40
60Cycle 1
Cycle 10
Cycle 20
Relative Area
0,0 0,2 0,4 0,6 0,8 1,0 0,0 0,2 0,4 0,6 0,8 1,0
Control rHV sHV
Dynamic cycles
Chapter 2 147
4.3.3. Presence of pulmonary surfactant functionality inhibitors.
Previous studies in our laboratory demonstrate that C-Reactive Protein (CRP) and
lipid peroxidation are main causes of surfactant impairment in VILI (Chapter 1).
CRP is an acute-phase protein that inhibits pulmonary surfactant by binding to it
when reaches the alveolar space (333). As we can see in Figure 12b, CRP to PL ratio
significantly increased in sHV group compared with Control (p<0.01) (n=3 per
group).
On the other hand, is widely accepted that mechanical stress stimulates ROS
production (292). As a result, this oxidative environment directly affects PS by lipid
peroxidation of LA. We observed a significant increase of LA lipid peroxidation in
sHV group in contrast with rHV (p<0.05) in Figure 12d (n=4 per group).
Finally, we also assessed total protein and Ch content in LA in five and four
animal per group respectively, as they are considered potential inhibitors of PS
functionality (296). Accordingly, we observed a significant increase of both, protein
to PL ratio in LA (p<0.001 vs. all groups) and the molar percentage of Ch to PL ratio
in LA of sHV group (p<0.05 vs. Control and rHV) (Figure 12a and 12c). These data
suggest alterations in LA composition as well as plasma protein contamination, which
may lead to surfactant biophysical activity impairment.
Therefore, the presence of all these factors contributes to PS functionality
dysfunction.
Chapter 2 148
Figure 12: Presence of pulmonary surfactant inactivators in all groups of study.
a) Total protein to PL ratio in LA was assessed in five animals of all groups of study. This
ratio significantly increases in sHV group as a result of plasma-derived proteins
contamination.
b) CRP was measured using a rat CRP ELISA kit. CRP to PL in pulmonary surfactant ratio
significantly increased in sHV (n=3 per group).
c) Analysis of Ch was performed using an enzymatic colorimetric kit (n=4 per group).
Molar percentage of Ch to PL ratio in LA of sHV significantly increases vs. Control and
rHV groups.
d) Lipid hydroperoxides were quantified in lipid extracts of LA from n=4 animals per group
by FOX method. Lipid hydroperoxides significantly increase in LA of sHV group vs. rHV
group.
Data represent mean ± S.E.M. *p<0.05 and **p<0.01 vs. Control; ***p<0.001 vs. all
groups; #p<0.05 vs. rHV.
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
Ch/PL
% M
ola
r C
h/P
L in
LA
0
10
20
30
LV rHV sHVC
* #
PG TNF/ML BAL PG TNF/ML BAL
Lipid peroxidation
0
10
20
30
40
LV rHV sHV
#
pm
ol H
P/ nm
ol P
L in L
A
C
c) d)
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
Prot/PL
0,0
0,2
0,4
0,6
0,8 ***m
g p
rot/
mol P
L in L
A
LV rHV sHVC
a)
0
1
2
3
4
5
6
7
CRP/PL
**
LV rHV sHVC
C
RP
/To
tal P
L w
t
b)
Chapter 2 149
5. DISCUSSION
This study demonstrated that under the same injurious MV stress,
experimental animals had two different outcomes: a susceptible response (sHV) or a
resistant outcome to injurious MV (rHV). These two phenotypes almost differed in all
levels studied involving several factors.
Previous studies in our laboratory observed a relationship between MV and a
reduction of total number of fluid cells (Chapter 1), being remarkable under injurious
MV. In this research we also observed this pattern together with a decrement of
alveolar macrophages in HV groups, being stronger in sHV group. Furthermore, this
decrease was accompanied by an injury score increase in HV groups, characterized by
presence of capillary congestion, type I pneumocyte necrosis and hyaline membrane
formation covering the denuded epithelial surface, being noteworthy in sHV. As
hyaline membranes are composed by cellular debris and fibrin, our data suggest that
alveolar macrophages from sHV group are more susceptible to overinflation produced
by high VT and PEEP absence and therefore to necrosis, comprising part of hyaline
membranes. Conversely, alveolar macrophages from rHV group may be more
resistant to overinflation as proof their higher rates. Therefore, it is reasonable to
suggest that MV itself directly affects to alveolar cells by several mechanisms
depending on their susceptibility. Interestingly, this susceptibility may also explain
the different inflammatory responses observed in HV groups.
IL-6 is a typical early inducible cytokine synthesized by many cell types
participating in initiation and regulation of inflammation (213, 359). Interestingly,
while there is no doubt about the proinflammatory role of other early inducible
cytokines such as TNF-α and MIP-2 after applying an insult to the lung, IL-6 seems to
be more than a merely acute phase reaction-inducing cytokine (353), it should be
defined as a resolution factor that balances pro- and anti-inflammatory outcomes to
further the immunological response (213). In fact, some studies of acute inflammation
demonstrated that the lack of IL-6 was related with higher levels of MIP-2 and TNF-
α, which in high doses is considered a pathological inflammatory mediator causing
cells activation and affecting permeability in combination with other cytokines (353,
359). Our results indicate a possible modulator role of proinflammatory cytokine sby
IL-6 as we observed a contradictory pattern in HV groups: while in the alveolar fluid
of rHVgroup IL-6 levels significantly increased, TNF-α, MCP-1 and MIP-2 levels
Chapter 2 150
were slightly increased, whereas in BAL of sHV group TNF-α, MCP-1 and MIP-2
significantly increased while IL-6 remained at basal levels. Furthermore, TNF-α/IL-6
ratio, as well as MIP-2/IL-6 ratio and MCP-1/IL-6 ratio significantly increased in
sHV group while remained similar in rest of groups. These data suggest a regulation
role of IL-6 in rHV that is altered in sHV group leading to an exacerbated
proinflammatory status. It is important to note that the only significant difference
observe in plasma of ventilated groups was in sHV where MIP-2 levels significantly
increased, suggesting a loss of compartmentalization.
All these data suggest that alveolar cells from HV groups had different responses
to MV with high VT and absence of PEEP, which may entail an attenuated or
exacerbated inflammatory response in the alveolar space leading to different
outcomes.
Also, as previously detected in our laboratory (Chapter 1), we observed an
increase of ASMase activity in BAL of sHV group without changes in plasma levels
among groups. Interestingly, ASMase activity-derived ceramide increase is involved
in permeability alterations and promotes edema formation in models of ALI (336).
Here, we observed a significant increase of total protein in the alveolar space
only in sHV group, suggesting edema presence probably due to alterations in the
alveolar-capillary barrier while considering the increase of cytokines release as a
contributor of this protein increment. Interestingly, an activated proinflammatory
status in the alveolar space is considered a main contributor of alterations in alveolar-
capillary barrier and tissue injury (173), which are usually linked (235), as we also
detected in sHV group. Therefore, these data support the hypothesis that the same
stress may induce different activation pathways that leads to an attenuated or
exacerbated outcome depending on their susceptibility to injurious MV.
Indeed, we detected other factors that are known to be contributors of alveolar-
capillary alterations in VILI. Many studies reported that ventilation with elevated PIP
promotes edema (235) as well as few studies reported an increase of PIP values
among time under injurious MVstrategies (296, 360). Here we observed a significant
increase of PIP in sHV group in contrast with rHV group just at the beginning of
high-stretch strategy setup that is aggravated at 1h of injurious MV. This result led us
to speculate that PIP under VT fixated strategies might be an early marker of MV
susceptibility.
Chapter 2 151
As well, another contributor to alter alveolar-capillary barrier leading to edema
formation is PS impairment (298). An alteration in PS functionality by increasing
surface tension at the air-liquid interface in the alveoli not only alters the gradient
pressures across the barrier but also leads to decrease pulmonary compliance,
atelectasis and hypoxemia associated with anaerobic metabolism (9, 298).
Interestingly, we have detected these physiological alterations related with surfactant
impairment and PIP increased values in sHV group while rHV had a proper
functionality. We observed alterations in interfacial adsorption of sHV using two
different techniques. As well, we further evaluated the other dynamic properties of PS
detecting a surface tension decrease upon compression that did not reach appropriate
values as well as an inefficient re-extension upon expansion of sHV group. Besides
PS impairment in sHV, there was also a change in endogenous PS system and its
composition.
Several studies reported the conversion of the active fraction of PS (LA) to the
inactive fraction (SA) as a primary mechanism of PS impairment, being considered an
increase in SA/LA ratio as a damage marker of VILI (298, 361). Here, we observed
an alteration of SA/LA conversion in sHV together with a decrease in RNA levels and
protein levels of PS-associated proteins, an increase of Ch values relative to PL
amount in LA and presence of lipid peroxidation in LA. These findings are consistent
with similar results previously obtained in our laboratory (Chapter 1) and other
studies using ex vivo models (294, 297). However, PS from rHV group had an
opposite outcome. We observed adequate biophysical dynamic properties and
optimum levels of PS-associated proteins, Ch and absence of peroxidation in this
group.
Interestingly, both injuriously MV groups had in common an increase of total PS
release into the alveolar space. Previous studies, including ours, have demonstrated
that high VT ventilation increased PS secretion (Chapter 1) (296). However, while
rHV group had significantly increased the LA pool without changes in SA, sHV
group has the opposite pattern. Therefore injurious MV induced PS release into the
alveolar space but depending on animal susceptibility may be rapidly altered probably
due to the exacerbated inflammatory status in the alveolar space or may remain stable
probably helping to ensure the attenuated response to injurious MV. As a result, a
proper maintenance of PS against VILI may contribute to attenuate immune
responses, as some studies reported immuno-modulator properties of PS PL (88, 148)
Chapter 2 152
as well as maintain the alveolar barrier integrity.
In fact, it is worth highlighting that PS alterations contributing to edema presence
provokes a vicious circle of surfactant inactivation as several plasma-derived proteins
are able to even compete with PS for reaching the air-liquid interface (6) or directly
binding to it. In this research we have detected protein contamination in LA in sHV
group as well as a significant increase of CRP, an acute-phase protein that inhibits PS
functionality by binding to it (Chapter 1) (333).
To summarize, we demonstrated that injurious MV could develop two different
outcomes according to the animal susceptibility. The main factor that seems to
contribute to protect the lung against injurious MV is an attenuated inflammatory
response where IL-6 seems to play a key role. As a result, lack of edema, tissue injury
or PS alterations are the main characteristic factors of this resistant outcome against
VILI. Interestingly, our data indicated that VILI occurred only in animal models when
surfactant is inactivated. Therefore, these results show that there is a direct link
between pronounced proinflammatory response and surfactant inactivation.
Consequently, we suggest that the best approach for early intervention, prior to
exposition to mechanical ventilation, would be the administration of antiinflammatory
agents. Given the beneficial effects of high surfactant secretion in survival animals
exposed to high VT, surfactant-like nanoliposomes could be useful as carriers for
delivering antiinflammatory agents to the alveolar spaces. Surfactant-like vesicles
used as a vehicle could ensure drug contact with the alveolar spaces and could
increase the potency of anti-inflammatory agents on alveolar epithelial cells and
macrophages, facilitating their entrance into the cells. At the same time, exogenous
surfactant administration could contribute to improve pulmonary function.
To conclude, these results depicts that an attenuated inflammatory response
together with increasing endogenous, fully active, lung surfactant into the alveolar
space prevents edema and a worsened outcome to high-stretch ventilation.
Chapter 3 153
Chapter 3
Effect of prolonged low-
stretch ventilation after
injurious high-stretch
ventilation in resistant rats
Chapter 3 154
Chapter 3 155
1. ABSTRACT
The aim of the present study was to elucidate the effect of prolonged
conventional low-stretch ventilation, with or without previous exposition to injurious
high-stretch ventilation.
Sprague-Dawley rats were randomly assigned to control conditions (no MV), low-
stretch ventilation during 8.5 h (LV) [Tidal volume (VT) = 9 ml/kg, positive-end
expiratory pressure (PEEP) = 5 cm H2O] or injurious ventilation [VT = 25 ml/kg, PEEP
= 0cm H2O] during 2.5 h followed by 6 h of low stretch-ventilation (HV+LV).
Subsequently, lung tissue, plasma, bronchoalveolar fluid (BAL), BAL cells, and
isolated surfactant were analyzed.
Animals subjected to prolonged low-stretch MV after high-stretch ventilation had
two different outcomes according to their susceptibility. Susceptible animals s(HV+LV)
had a characteristic ventilator-induced lung injury (VILI) outcome distinguish by
surfactant alterations, proinflammatory cytokines increase in BAL, edema and
hypoxemia (PaO2/FiO2<200 mmHg). Resistant animals r(HV+LV) were characterized
by alterations in the alveolar capillary-barrier, an increase of neutrophils in BAL,
increased levels of MIP-2 and ASMase activity in plasma and slight alterations in gas
exchange. Animals exclusively subjected to low-stretch ventilation strategies developed
inflammatory changes without histological or physiological alterations.
To conclude conventional low-stretch ventilation length is directly related with the
development of lung inflammation regardless of whether animals were or not previously
exposed to high-stretch ventilation. In this context, lung surfactant alterations do not
precede the onset of acute lung injury induced by prolonged low-stretch ventilation after
high-stretch ventilation but its proper functioning is essential for survival.
2. INTRODUCTION
Numerous direct and indirect pulmonary clinical factors contribute to develop acute
lung injury (ALI) hampering the assessment of its remarkable incidence (173). Despite
of the etiological variability of this syndrome, its mortality rates has successfully
decreased over the last two decades (173). The main factor contributing to this
decrement is the improvement of mechanical ventilation strategies (MV). In fact, MV is
an integral part of ALI therapy, but an inappropriate application can lead to side effects,
Chapter 3 156
called ventilator-induced lung injury (VILI) (299). To date, limiting VILI through lower
tidal volumes (VT) is the only intervention demonstrated to reduce ALI mortality rates
(362). However, some clinical trials have been developed to determine the possible
effects of low VT MV parameters (363).
Conversely, other clinical studies concluded that even applying the same MV stress
to different patients, forces reaching to alveolar cells and their corresponding response
are quite heterogeneous and variable (299), presuming that a personalization of the
ventilator strategies according to the patient‟s condition will improve the outcome
(349).
As clinical studies provide descriptive data about the onset and evolution of ALI
leading to hypothesize about its mechanisms of injury, animal models yield
straightforward methods to study in depth those assumptions.
The most frequent animal model of ALI is the application of MV (232) due to its
clinical relevance (173).As a result, several harmful protocols characterized by the
application of high VT, high peak-pressures and/or the lack of positive end-expiratory
pressure (PEEP) have been performed to characterized VILI (7). Generally, VILI
models are no longer ventilated than 8 h depending on ventilatory settings and support
(206), being usual to not exceed 4 h of high VT or peak-pressures in rodents due to
survival (206, 305, 364). These high-stretched models result in alveolar hemorrhage,
hyaline membranes formation, neutrophilic infiltration, decreased compliance and gas-
exchange abnormalities (232). Interestingly, a previous study in our laboratory
described two different outcomes to the same injurious MV strategy, highlighting the
existence of variability in stress susceptibility to MV in animal models (Chapter 2).
Conversely, some experimental models recently studied the possible adverse effects of
low VT ventilation (286). Indeed, even there are many studies concerning the
application of protective MV combined with other insults (365), little research has been
performed related to the possible effects of protective MV after the induction of lung
injury, specifically VILI (206).
Therefore, the aim of the present study was to characterize the effect of prolonged
low VT MV and specifically in animals resistant to previous application of injurious
MV. To accomplish this objective, we established a rodent model of low or high VT MV
during 2.5 h followed by 6 more hours of low VT MV to characterize the physiological,
inflammatory and pulmonary surfactant changes in the lung.
Chapter 3 157
3. EXPERIMENTAL PROTOCOL
Male Sprague-Dawley rats were randomly distributed in the following groups:
Control group (n=5): animals undergoing identical anesthetic and surgical
procedures than the other groups but without applying MV.
Low-stretched group during 8.5 h. (LV) (n=7): animals subjected to protective
MV parameters during 2.5 h followed by 6 more hours under this ventilation
protocol until their sacrifice.
High-stretched group during 8.5 h. (HV+LV) (n=10): animals subjected to
injurious MV parameters during 2.5 h followed by 6 more hours applying
protective MV until their sacrifice. Interestingly, some of the animals subjected
to this MV protocol did not survive to the 6 h of protective MV. As a result, we
obtained two groups: animals that finished the experimental protocol
[r(HV+LV), n=7] and animals that did not reached the 8.5 h of MV [s(HV+LV),
n=3].
Figure 1: Experimental design. Representation of all groups established for the study
subdivided according to the mechanical ventilation strategies.
Experimental design
Control (C): non-ventilated rats; n=5.
Settling time
30 min
t: 0 h t: 2.5 hLV
n=7
VT=9 ml/kg
5 cmH2O PEEP VT=9 ml/kg, 5 cmH2O PEEP
t: 8.5 h
t: 0 hHV + LV
n=10 Settling time
30 min
VT=25 ml/kg
0 PEEP
Dead
s(HV + LV)
n=3
r(HV + LV)
n=7
VT=9 ml/kg, 5 cmH2O PEEP
t: 2.5 h t: 8.5 h
Chapter 3 158
In all ventilated groups, respiratory rate was 70 bpm, inspiratory time 0.35 sec.,
expiratory time 0.56 sec. and FiO2 0.35. Animals were ventilated for an equilibration
period of 30 min using the low VT ventilation parameters. Then, the assigned VT was
administered starting at t=0 min.
Hemodynamic and ventilatory parameters were registered at t=0 min, t=2.5 h and
t=8.5 h. Blood samples were collected at the beginning and end of the ventilatory
procedure to gases analysis.
Animals were sacrificed by exsanguination after the established ventilatory period
and subsequently we proceeded to sampling. We obtained lung tissue and
bronchoalveola rlavage that it was separated from the alveolar fluid cells by
centrifugation. The remaining bronchoalveolar lavage free of cells (BAL) was
processed to obtain pulmonary surfactant (PS).
4. RESULTS
4.1. Alterations under long exposure to MV
4.1.1. Physiology
Lung function [peak inspiratory pressure (PIP) and respiratory system compliance
(CRS)] were significantly altered in s(HV+LV) group in contrast with r(HV+LV) group
just starting injurious MV as depicts Figure 2.
Figure 2: Changes during the ventilator period in peak inspiratory pressure (PIP) and
respiratory system compliance (CRS) in rats ventilated with Low or High tidal
volumes.
PIP and CRS were measured at baseline, start and after 2.5 and 8.5 hours of mechanical
ventilation according to the experimental protocol requirements.
Data represent mean ± S.E.M. *p<0.05 and **p<0.01 vs. r(HV+LV) group.
PIP
Basal
cm
H2O
0
10
20
30
40 LV
r(HV+LV)
s(HV+LV)
0 h 2.5 h 8.5 h
MV time
*
*
*
Compliance
Basal
mL/c
m H
2O
0,0
0,1
0,2
0,3
0,4
0,5
0,6
0,7LV
r(HV+LV)
s (HV+LV)
0 h 2.5 h 8.5 h
MV time
*
***
Chapter 3 159
As well, mean arterial pressure (MAP) and arterial partial pressure of oxygen
(PaO2)-to-fractional inspired oxygen (FiO2) ratio were significantly decreased at 8.5 h in
s(HV+LV) group together with a significant increased of arterial partial pressure of
carbon dioxide (PaCO2) in this group (Figure 3). Interestingly, PaO2/FiO2 ratio was also
slightly decreased in r(HV+LV) group, without reaching the damaging values fixed by
the ARDSnet (2).
These data suggest alterations in gas exchange and atelectasis in s(HV+LV).
Figure 3: Changes during the mechanical ventilation (MV) period in hemodynamic
variables in rats ventilated groups with Low or High tidal volumes.
a) Mean arterial pressure (MAP) was measured at baseline, start and after 2.5 and 8.5 hours of
MV. b) Arterial partial pressure of oxygen (PaO2)-to-fractional inspired oxygen (FiO2) ratio
values were assessed before and after 2.5 and 8.5 hours of MV. c) Arterial partial pressure of
carbon dioxide (PaCO2) was evaluated before and after 2.5 and 8.5 hours of MV.
Data represent mean ± S.E.M. *p<0.05 vs. Control and*** p<0.001 vs. all groups.
MAP
Basal
mm
Hg
0
20
40
60
80
100
120
140 LV
r(HV+LV)
sHV
0 h 2.5 h 8.5 h
MV time
***PaCO
2
Basal
mm
Hg
0
15
30
45
60
75
90 LV
r(HV+LV)
sHV
2.5 h 8.5 h
MV time
*
a)
PaO2/FiO
2
Basal
mm
Hg
0
100
200
300
400
500
600LV
r(HV+LV)
sHV
2.5 h 8.5 h
MV time
***
*
b)
c)
Chapter 3 160
4.1.2. Alveolar injury
Changes in the alveolar space due to long exposure to MV were characterized
evaluating presence of edema and alveolar fluid cells alterations as well as assessing the
histological score and damage markers levels.
4.1.2.1. Intra-alveolar edema and histological injury score
Histological score revealed significant alterations in s(HV+LV) group whereas
edema presence, represented as total amount of proteins in BAL, had an increasing
trend in both HV groups, being significant in s(HV+LV) group (Figure 4).
4.1.2.2. Alveolar fluid cells
Total cell counts in BAL presented a decreasing trend when prolonged MV is
applied. In particular, cell counts significantly decreased in s(HV+LV) group (Figure
5a, left panel). In addition, the proportion of alveolar macrophages significantly
decreased in all HV groups. Interestingly, only neutrophils proportion was significantly
raised in r(HV+LV) group though there was an increasing trend in all prolonged MV
groups (Figure 5b, right panel), suggesting that prolonged protective MV may promote
Figure 4: Alveolar injury in the different experimental groups.
a) Edema presence was measured as total protein content in bronchoalveolar fluid.
b) Histological score was assessed by hematoxylin-eosin staining of isolated and fixated
left lungs of all groups.
Data represent mean ± S.E.M. *p<0.05 vs. Control and ***p<0.001 vs. all groups.
0
10
20
30
40
50
60
LVC r(HV+LV) s(HV+LV)
*
mg
pro
tein
/kg
bod
y w
eig
ht
Total protein in BAL
0
10
20
30
40
50
60
70
LVC r(HV+LV) s(HV+LV)
***In
jury
score
Histological scorea) b)
Chapter 3 161
neutrophils infiltration in the alveolar space together with alveolar macrophages
decrement.
Hence, MV may change alveolar fluid cells profile as depict the representative
flow cytometric side scatter (SSC, relative complexity)/forward scatter (FSC, relative
size) dot plots from all experimental groups (Figure 5b).
Figure 5: Alveolar fluid cells profile in all experimental groups.
a) Left panel represents total cell counts recovered in BALdetermined by assessing cell
viability with trypan blue dye exclusion. Data represent mean ± S.E.M. *p<0.05 vs. Control.
Right panel depicts the proportion of alveolar macrophages and neutrophils in BAL fluid
determined by fluorescence flow cytometry assays using specific monoclonal antibodies
(anti-CD11c for alveolar macrophages and anti-RP-1 for blood neutrophils). Data represent
mean ± S.E.M. *p<0.05 vs. Control of neutrophils. #p<0.05 and
##p<0.01 vs. Control of
alveolar macrophages.
b) Representative side scatter (SSC)/forward scatter (FSC) dot plots of the flow cytometric
profile of total alveolar fluid cells from all groups of study.
% c
ells
in B
AL
0
10
20
30
40
50
60
70Macrophages
Neutrophils
LVC r(HV+LV) s(HV+LV)
*##
#
0,0
5,0e+5
1,0e+6
1,5e+6
2,0e+6
BA
l cell
counts
LVC r(HV+LV) s(HV+LV)
*
Control LV
r(HV+LV) s(HV+LV)
a)
Alveolar fluid cells profile
Representative SSC/FCS scatterplotsb)
Chapter 3 162
4.1.2.3. Damage markers
We determined the presence of the inflammatory cytokines TNF-α, IL-6, MIP-2
and MCP-1 in BAL (Figure 6a) and plasma (Figure 6b). In addition, we studied the acid
sphingomyelinase (ASMase) activity in these fluids as well as its RNA levels in lung
tissue (Figure 7).
Cytokines results indicated an exacerbated increase of all the cytokines studied in
BAL in s(HV+LV) group. Furthermore, we observed a significant increase of IL-6 and
MIP-2 levels in plasma in this group while TNF-α was undetectable in all groups and
MCP-1 plasma levels did not change among groups (data not shown). It is worth noting
that we observed a significant increase of MIP-2 levels in BAL and plasma of
r(HV+LV) group, chemokine tightly related with neutrophils recruitment. Interestingly,
we also observed changes in the low-stretched group. Specifically, we detected a
significant increase of MIP-2 and IL-6 levels in BAL. Moreover, we observed an
increase of IL-6 levels in plasma in LV group and also in r(HV+LV) group.
These data suggest an activation of inflammatory processes under prolonged MV
even under protective strategies.
According to the results related to ASMase activity, we did not observe changes
among groups in BAL, whose values were lower than those obtained in plasma.
Conversely, we detected a significant increase of this enzymatic activity in plasma
together with a significant increase of its RNA expression in lung tissue in r(HV+LV)
group. These data let us to speculate that prolonged conventional MV after high-stretch
MV up-regulates ASMase production and release to the bloodstream and therefore
activating ASMase-derived ceramide pathway a promoter of several routes leading to
ALI (332).
Chapter 3 163
0
2
4
6
8
10
12
14
16***
TN
F- (
pg/m
l)
BAL
0
50
100
150
200
250
300
LVC r(HV+LV) s(HV+LV)
***
IL-6(
pg/m
l)
*
0
100
200
300
400
500
600
*
MC
P-1(
pg/m
l)
BAL
0
50
100
150
200
250
300
350
400
LVC r(HV+LV) s(HV+LV)
***
MIP
-2(p
g/m
l)
*
0
20
40
60
80
100
LVC r(HV+LV) s(HV+LV)
**
IL-6(
pg/m
l) *
Plasma
*
0
10
20
30
40
LVC r(HV+LV) s(HV+LV)
**
MIP
-2(
pg/m
l)
Plasma
**
*
a)
b)
Figure 6: Inflammatory cytokines detected in all the experimental groups.
All cytokines were measured in BAL and plasma by colorimetric rat ELISA kits following
the instructions provided by the supplier. TNF-α levels in plasma were undetectable and
MCP-1 levels in plasma did not changed among groups (data not shown).
Data represent mean ± S.E.M. *p<0.05 and **p<0.01 vs. Control; ***p<0.001 vs. all
groups.
Chapter 3 164
4.1.3. Pulmonary surfactant analysis
Pulmonary surfactant (PS) is comprised of 90% lipids, predominantly
phospholipids (PL), and 10% of proteins, mainly the PS-associated proteins: SP-A, SP-
B, SP-C and SP-D. PS is secreted into the alveolar space by alveolar type II cells (ATII)
as high-organized lipoprotein structures capable of establishing a surface film that
stabilize the alveoli by the reduction of the surface tension at the air-liquid interface.
This function is accomplished by PS large aggregates (LA), which may be transformed
to a non-functional fraction, called small aggregates (SA), due to compression and
expansion movements during respiration (314). Under pathological situations, LA to SA
conversion is altered, being the SA/LA ratio increase a damage marker of VILI.
Therefore, we assessed PS biophysical function as well as presence of protein
contamination in LA which is considered a potential inhibitor of PS functionality (296).
Also, we evaluated possible alterations in LA to SA conversion and determined PS-
associated protein levels in LA (Figure 8).
Pulmonary surfactant biophysical function was determined performing an
interfacial adsorption assay. The ability of LA to adsorb onto and spread at the air–
water interface was measured using a Wilhelmy-like high-sensitive surface
microbalance, coupled to a teflon dish of very small size by following the variation in
Figure 7: Acid sphingomyelinase activity in BAL and plasma and its RNA expression
in lung tissue of all experimental groups.
a) RNA expression of ASMase was detected using total RNA isolated from the lower lobe
of the right lung. cDNA synthesis was performed using 1µg total RNA as input and it was
amplified by RT-PCR using specific primers. Results were analyzed using ΔΔCT method
and expressed as normalized fold expression. b and c) ASMase activity in BAL and
plasma measured performing an enzymatic assay. ASMase activity values in BAL were
similar between groups and smaller than the values observed in plasma.
Data represent mean ± S.E.M.*p<0.05 and ** p<0.01 vs. Control.
0,0
0,5
1,0
1,5
2,0
2,5
3,0
LVC r(HV+LV) s(HV+LV)
Fold
change
ASMase gene expression
**
a)
0
50
100
150
200
250
300
LVC r(HV+LV) s(HV+LV)
nm
ol[
14C
]-P
-Cholin
e/m
L/h
Plasma ASMase
0
50
100
150
200
250
300
LVC r(HV+LV) s(HV+LV)
nm
ol[
14C
]-P
-Cholin
e/m
L/h
BAL ASMase
*
b) c)
Chapter 3 165
surface pressure as a function of time, as previously described (322). This ability is
significantly impaired in s(HV+LV) group at 30 min as represents figure 8a.
Accordingly, we observed a significant increase of SA/LA ratio in s(HV+LV)
group, indicating alterations in PS conversion probably due to the alterations detected in
the alveolar space (Figure 8b). Specifically, we observed protein contamination in the
active fraction of s(HV+LV) group (Figure d) which may alter PS function. Also, the
variation on PS-associated proteins levels might be considered as another marker of
alveolar alterations due to injurious MV that directly affects PS (Chapter 1 and 2). As a
result, we observed no difference among groups of SP-A protein levels in LA (data not
shown). Conversely, we observed a significant decrease of SP-B and SP-C levels in
s(HV+LV) group.
Figure 8: Pulmonary surfactant alterations due to prolonged mechanical ventilation.
a) Surfactant interfacial adsorption was determined in all groups of study in a Wilhelmy-
like high-sensitive surface microbalance by following the variation in surface pressure as a
function of time. Interfacial adsorption was impaired in s(HV+LV) group. b) LA to SA
conversion as the ratio of PL content between SA and LA of all experimental groups. This
ratio significantly increased in s(HV+LV) group. c) Pulmonary surfactant-associated
proteinswere detected by Western blot analysis (WB) in LA samples. Proteins
quantification was achieved by densitometric evaluation of the bands obtained in WB. SP-
B and SP-C levels significantly decreased in s(HV+LV) group. d) Total protein to PL
ratio in LA was assessed in all groups of study. This ratio significantly increased in
s(HV+LV) group.
Data represent mean ± S.E.M. * p<0.05, **p<0.01 and ***p<0.001 vs. Control.
SP
-B a
nd S
P-C
(%
Contr
ol)
0
30
60
90
120
SP-B
SP-C
LVC r(HV+LV) s(HV+LV)
**
Western Blot band Intensity
*
mN
/m)
Control
r(HV+LV)
LV
s(HV+LV)
Interfacial Adsorption
Time0 10 20 30
0
10
20
30
40
50
C
LV
r(HV+LV)
s(HV+LV)
***
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
SA
/LA
0,0
0,5
1,0
1,5**
LVC r(HV+LV) s(HV+LV)
SA/LA
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
PG TNF/ML BAL PG TNF/ML BAL
mg p
rot/m
g P
L in L
A
0
5
10
15
20
***
LVC r(HV+LV) s(HV+LV)
Prot/PL
a) b)
d)c)
Chapter 3 166
4.2. Comparison between short and long exposure to MV under the same
ventilation strategy.
In order to discern possible factors attributable to longer exposure to MV under
conventional parameters we compared these data with the results obtained from the
resistant groups to high-stretch MV studied in Chapter 2 (Table 1). As well, we assessed
neutrophils proportion in BAL of n=5 rats per group under short strategies used in
Chapter 2 to compare neutrophil infiltration values between short and long exposures to
MV (Table 1). Furthermore, we also studied gene expression in lung tissue of factors
usually observed in a later-stage of ALI such transforming growth beta (TGF-β) and
matrix metalloproteinase-2 (MMP-2) in short and long-ventilated rats under both MV
strategies (Figure 9).
Interestingly, in Table 1 we observed differences between HV groups but also
among LV groups, suggesting that prolonged MV even under conventional strategies
lead changes in the alveolar space. Specifically, we observed a significant increase of
neutrophils percentage in the alveolar fluid along with a significant increase of
chemokines (MCP-1 and MIP-2) and IL-6 in BAL in prolonged conventional
mechanical ventilated animals in contrast with the short low-stretched group. Also we
observed a significant increase of IL-6 in plasma in the prolonged low-stretched group.
However, SP-A protein levels significantly decreased in the prolonged low-stretched
group in contrast with the short LV group.
On the other hand, rHV and r(HV+LV) differed in almost all variables represented
in Table 1. In particular, r(HV+LV) group was characterized by an increase of edema
presence, neutrophils percentage and MIP-2 and IL-6 levels in plasma in contrast with
rHV group. Conversely, the levels of the early inducible pleiotropic cytokines involved
in acute inflammatory responses TNF-α and IL-6 (331, 353) were significantly decrease
in BAL of r(HV+LV) group in contrast with rHV. However, MCP-1 and MIP-2 levels,
chemokines involved in the attraction of leukocytes like monocytes, lymphocytes or
neutrophils (355, 366, 367) were similar among rHV and r(HV+LV) groups and higher
than in control group. Interestingly, rHV had a significant increase in PS secretion
levels and SP-A protein levels.
Chapter 3 167
We also analyze TGF-β and MMP-2 gene expression in lung tissue from all the
experimental groups of this Chapter and Chapter 2.
TGF-β1 RNA expression levels revealed a significant increase of its expression in
r(HV+LV) group. On the other hand, Matrix metalloproteinase 2 (MMP-2) is a zinc-
dependent endopeptidase that degrades several components of the extracellular matrix
Table 1: Differences between resistant animals subjected to short (2.5h) or long
exposure (2.5h + 6h) to mechanical ventilation (MV) under conventional (Low tidal
volume [VT]) or injurious (High VT) MV strategies.
Definition of abbreviation: BAL: bronchoalveolar lavage; TNF-α: Tumor necrosis factor alpha;
IL-6: Interleukin 6; MIP-2: macrophage inflammatory protein 2; MCP-1: monocyte chemotactic
protein 1. PS: pulmonary surfactant; SP-A: pulmonary surfactant-associated protein A; WB:
western blot.
All factors were measured at the end of the ventilator period. Data are mean ± S.E.M; A two-
tailed unpaired Student T-test was performed between groups of the same mechanical
ventilation strategy. * p<0.05, **p<0.01 and p<0.001 vs. LV; #p<0.05 and
##p<0.01 vs. HV.
Variables
Groups
Control
Low VT MV Resistant to High VT MV
2.5h 2.5h + 6h 2.5h 2.5h + 6h
(Low VT)
Edema
(BAL
protein)
11.91±1.57 9.2±0.83 10.19±1.04 11.65±1.51 36.6±9.8#
%
Neutrophils
in BAL
2.65± 0.43 3.24±0.87 7.53±1.3* 3.65±0.73 9.74±2.39#
TNF-α
(BAL) 0.7±0.46 1.15±0.75 1.58±0.92 9.3±2.4
# 2.65±1.17
IL-6 (BAL) 93.1±11.88 40.64± 4.04 136.9±6.4*** 130.7±5.7##
89.58±8.75
MIP-2
(BAL) 22.28±4.05 32.5±6.5 137.55±26.58** 147.55±36.69 147.55±32.82
MCP-1
(BAL) 68.38±12.49 18.35±3.24 148.37±34.39* 126.99±24.28 92.75±28.71
IL-6
(Plasma) 29.12±5.98 40.5±2.3 59.975±7.575* 43.73±0.48 56.3±4.75
#
MIP-2
(Plasma) 10.04±1.58 8.1±2.1 8.78±1.33 13.66±1.82 25.27±3.09
#
PS
secretion 4.03±0.04 2.66±0.44 2.9±0.6 7.34±0.66
# 4.58±0.73
SP-A (WB
band
intensity)
100% 174.07±9.83*** 79.74±3.56 185.73±26.95# 86.58±9.01
Chapter 3 168
(ECM), including type IV collagen and laminin (368). Our data indicated that MMP-2
RNA expression overcame a significant decrease in all HV groups and long-exposure
animals to conventional MV.
5. DISCUSSION
This study highlights that prolonged low-stretch MV usually applied in clinic, has
effects not as harmless as could be expected. Thus, animals ventilated under the same
low-stretch MV strategy during all the experimentdeveloped an inflammatory status in
the alveolar space. However, animals subjected to previous high-stretch MV having a
resistant outcome before prolonged low-stretch MV developed two different responses
according to their resistance.
In line with the results previously obtained in our laboratory (Chapter 1 & 2), we
observed that MV decreased total alveolar cells counts, being significantly decreased in
s(HV+LV) group. Suitably, alveolar macrophages proportion had also a decreasing
trend in all MV groups being significant in HV+LV groups. Interestingly, we also
detected an increasing trend in neutrophils percentage in MV groups, being significant
Figure 7: RNA expression of TGF-β and MMP-2 in lung tissue of animals exposed to
short or long exposure to MV under conventional or injurious strategies.
RNA expression of TGF-β and MMP-2 was detected using total RNA isolated from the
lower lobe of the right lung. cDNA synthesis was performed using 1µg total RNA as input
and it was amplified by qPCR using specific primers. Results were analyzed using ΔΔCT
method and expressed as normalized fold expression. Data represent mean ± S.E.M. *
p<0.05 and **p<0.001 vs. Control.
MMP-2
Fo
ld c
ha
ng
e0,0
0,2
0,4
0,6
0,8
1,0
1,2
1,4 LV
rHV
sHV
C
C 2.5 h 8.5 h
MV time
**
**
**
**
*
TGF-
Fo
ld c
ha
ng
e
0,0
0,5
1,0
1,5
2,0 LV
rHV
sHV
C
C 2.5 h 8.5 h
MV time
*
Chapter 3 169
in r(HV+LV) group. These data suggest that prolonged MV lead changes in the alveolar
fluid cells profile, due to neutrophils infiltration and macrophages decrease, as depicts
the side scatter/ forward scatter dot plot profile obtained by flow cytometry
measurements of alveolar fluid cells from all experimental groups. It is noteworthy that
the animals subjected to low or high MV strategies during 2.5 h had significantly lower
levels of neutrophils than prolonged MV groups suggesting that prolonged MV may
promote neutrophils infiltration in the alveolar space.
Furthermore, we studied the presence of MIP-2, also named CXCL-2, which is the
most relevant chemokine for neutrophil recruitment into the lung of rodents (369) and
its elevated expression exclusively in the alveolar compartment paralleled neutrophil
sequestration in VILI (367). Accordingly, we observed a significant increase of MIP-2
levels in BAL of all prolonged MV groups. Interestingly, this MIP-2 levels were similar
to those observed in the group resistant to 2.5 h of injurious MV studied in Chapter 2
[r(HV)]. Therefore, these data support the hypothesis that prolonged MV may induce
neutrophil recruitment into the alveolar space, being an important factor the over-
expression of MIP-2 in the alveolar compartment that may begin at early stages under
injurious MV. In fact, some studies suggested that short ventilator strategies applied in
small animals did not allow a massive recruitment (235). Nevertheless, our prolonged
MV model permits to assess the evolution of neutrophils recruitment to the alveolar
space.
Interestingly we also assessed a significant increase of MIP-2 levels in plasma only
in HV+LV groups, suggesting that this rising values might be considered as possible
damage biomarkers. Probably this increase might be related with the alveolar-capillary
barrier alterations observed in these groups without rejecting the possibility of MIP-2
release by other cells susceptible to the mechanical stress generated by this MV
strategy.
Alveolar-capillary barrier alterations were assessed measuring total protein content
in BAL of all groups, detecting a significant increase in both HV+LV groups.
Moreover, we observed presence of histological injury in both HV+LV groups being
significant in s(HV+LV) group. Conversely, we did not find a trail of histological
alterations or edema in LV group. Furthermore, the histological score values of
r(HV+LV) were similar to the values obtained in rHV group but total protein levels
differed due to a significant increase in r(HV+LV) group. Consequently, these data let
Chapter 3 170
us to speculate that prolonged MV after high-stretch MV promotes alterations in the
alveolar-capillary barrier.
As previous studies related neutrophils increment with hyaline membranes
deposition (264), basement membrane destruction and increased permeability of the
alveolar–capillary barrier (173, 206), we suspect that one of the main contributors to
these alterations in our HV+LV groups is neutrophils infiltration, being the increased
MIP-2 levels in plasma a good biomarker to realize it.
However, many other factors modulating inflammatory responses contribute to
explain their different outcomes.
Specifically, we observed an exacerbated proinflammatory status in the alveolar
space of s(HV+LV) group characterized by a significant increase of all cytokines
measured in BAL. However, r(HV+LV) group had only increased MIP-2 as previously
described. Furthermore, we observed that rHV had significantly increased TNF-and
IL-6 values in BAL in contrast with r(HV+LV) group explained by the fact that there
are considered early inducible proinflammatory cytokines involved in acute
inflammatory responses (331, 353). Conversely, we observed a significant increase of
IL-6 in LV group together with a significant increase of this pleiotropic cytokine in
plasma of all prolonged MV groups.
IL-6 is defined as a resolution factor that balances pro- and anti-inflammatory
outcomes to further the immunological response (213), suggesting a complex role for
IL-6 in lung injury (370). However, many studies reported a protective role of IL-6 by
the attenuation of lung inflammation or pulmonary edema (353, 370). Specifically, IL-6
limits alveolar barrier disruption and therefore edema, by reducing neutrophil contact
with the endothelium in VILI (370). These data support our findings, suggesting that an
increase of IL-6 in BAL may protect the alveolar space against alterations in the
alveolar-capillary barrier by limiting neutrophil contact with the endothelial cells in LV
group. Conversely, the basal levels of IL-6 observed in BAL of r(HV+LV) group may
not be enough to protect the alveolar-capillary barrier against neutrophils. Interestingly,
we observed a significant increase of IL-6 levels in plasma of all prolonged MV groups.
A wide range of cells besides cells from the alveolar compartment, including
fibroblasts, vascular endothelial and smooth muscle cells (SMC) secretes IL-6 (371).
Moreover, some studies suggest that alveolar SMC secreted IL-6 under certain
proinflammatory stimuli (372) and others detected that vascular endothelial and SMC
cells induced IL-6 expression under mechanical stress (373, 374). Therefore, we dare to
Chapter 3 171
speculate that prolonged MV might promote IL-6 release to the bloodstream by cells
closely related to the alveolar space suffering the mechanical stress.
Nevertheless, we have also reported other factors that may contribute to the
alteration of the alveolar-capillary barrier in r(HV+LV) group. Specifically, we detected
a significant increase of RNA expression of ASMase in lung tissue along with a
significant increase of its activity in plasma of r(HV+LV) group. ASMase is mainly
released by alveolar endothelial cells and has two subtypes, lysosomal and secretory
ASMase both derived from the same gene (SMPD1) (332). As we observed that
prolonged MV tend to stimulate ASMase RNA expression, only r(HV+LV) group had a
significant detection of its action exclusively in plasma while there is an absence of
ASMase activity increase either in BAL or plasma of the rest of groups. These results
suggest a secretory ASMase translation in r(HV+LV) group to the bloodstream.
Interestingly, secretory ASMase activity-derived ceramide is involved in alter vascular
permeability and promote edema formation when this enzyme is increased in plasma in
models of ALI (336). These data suggest that an increase of ASMase activity in plasma
may contribute to alter the alveolar-capillary barrier in r(HV+LV) group and might be
considered as possible damage biomarker of VILI.
On the other hand, it has been reported that an increase of TGF-ß1 gene expression
levels contributes to develop alveolar flooding in a model of bleomycin-induced lung
injury as well as is intimately related with an increase of ECM deposition in VILI (309,
375, 376). However, TGF-ß1 has a complex and critical role at late phases of ALI
leading to antagonistic outcomes due to the activation of different effector pathways
according to the presence of other stimuli in the alveolar space and the state of the target
cells (377). Thus, some studies reported that TGF-ß1 has an important antiinflammatory
and fibrotic effect inducing wound repair though other investigations concluded that
TGF-ß1 has a proinflammatory effect, promoting fibrogenesis and consequently
underlying the progression of tissue injury and fibrosis (376-378). Therefore, TGF-ß1
transcriptional responses seem to be involved in both inflammatory and proliferative
phases of ALI (378). Interestingly, we observed a significant increase of TGF-ß1 RNA
expression in lung tissue of r(HV+LV) group. This result suggests a possible
implication of TGF-ß1 in alveolar-capillary barrier alterations as well as a possible role
in the absence of hyaline membranes resolution, indicating a possible fibroproliferative
stage at the proliferative phase. Thus, future studies with prolonged MV periods may
elucidate this possibility.
Chapter 3 172
Many studies related the increase of the active presence of MMP-2 with acute
inflammation and fibrosis development in ALI and pulmonary fibrosis (379, 380).
Conversely, others described that MMP-2 active presence is a key factor of injury repair
and its inhibition seems to impair repair processes (206, 381). In this study we observed
a strong decrease of MMP-2 RNA levels in lung tissue observed in HV groups. As
some previous studies using models of mechanical stretch observed a significant
increase of MMP-2 levels in vitro (382) and in vivo (308, 379), a recent two-hit model
in vivo, detected a MMP-2 gene expression decrement after 8 h of MV (383). These
data suggest that MMP-2 RNA strong inhibition due to high MV contributes to
alterations in the alveolar space. However, though structural cells including fibroblasts,
endothelial and alveolar epithelial cells mainly secrete MMP-2, we cannot reject the
possibility of its release by leukocytes or even the release of other MMPs. Importantly,
an in vitro study observed that MMP-2 up-regulation by TGF-ß1 resulted in injury
repair (381). As we observed TGF-ß1 gene expression increment in r(HV+LV) group
we could speculate about possible up-regulation of MMP-2 in later phases. Therefore,
further investigation must be done in order to elucidate the pathway that leads to MMP-
2 inhibition as well as its contribution over time.
Previous studies in our laboratory observed that HV induced a significant secretion
of PS to the alveolar space (Chapters 1 and 2). Interestingly, rHV groups observed in
Chapter 2 had increased the active fraction of PS together with a significant increase of
SP-A protein levels in contrast with r(HV+LV) group which reached basal levels. SP-A
prevents the inhibition of PS by binding proteins (384), is involved in control PS
secretion and reuptake by alveolar cells and also contributes to maintain LA forms
during surface-area cycling by stabilizing tubular myelin and multilamellar structures,
avoiding LA to SA conversion (314, 385, 386). Therefore, SP-A may play a critical role
in PS homeostasis in resistant HV groups at short times that it is loss during prolonged
MV. Despite we did not found any trail of PS alterations in r(HV+LV) group, we
reported that s(HV+LV) had impaired PS functionality together with alterations in LA
to SA conversion (SA/LA ratio), total protein contamination in LA and significant
decrease of the hydrophobic peptides SP-B and SP-C. As previous studies in our
laboratory observed that animals susceptible to HV had associated PS alterations
(Chapters 1 & 2), we hypothesize that PS alterations are closely linked with an
exacerbated inflammatory status in the alveolar space of animals developing VILI.
Therefore, these data suggest that PS impairment is a damage marker of VILI.
Chapter 3 173
In fact, PS functional alteration by increasing surface tension at the air-liquid
interface in the alveoli is associated with alterations in the gradient pressures across
alveolar-capillary barrier, pulmonary compliance decrease, atelectasis and hypoxemia
(9, 298), as we also observed in s(HV+LV) group.
Furthermore, previous studies in our laboratory observed a relation between PIP
increment values and susceptibility to injurious MV, suggesting PIP as an early marker
of VILI (Chapter 2). Our results are consistent with these previous observations as
s(HV+LV) group significantly increased PIP values in contrast with r(HV+LV) group at
the beginning and during the high-stretch strategy setup. Furthermore after the
settlement of LV strategy, PIP values remained significantly higher in s(HV+LV)
groups while r(HV+LV) PIP values reached LV group values. Accordingly to these
results and taking into account that many studies reported that ventilation with elevated
PIP promotes edema (235), we hypothesize that PIP values under high VT strategies
might be an early marker of susceptibility to develop VILI.
To summarize prolonged low-stretch MV led changes in the alveolar space that
differed accordingly to the ventilation strategy applied. An exclusively prolonged low-
stretch ventilation strategy develops inflammatory changes that do not impact on
histological or physiological parameters. However, if prolonged low-stretch MV is
applied after high-stretch ventilation, we observed two different outcomes according to
their susceptibility. As a result, susceptible animals develop VILI characterized by PS
alterations, inflammatory exacerbation, edema and hypoxemia. Conversely, resistant
animals reveal alterations in the alveolar-capillary barrier together with neutrophils
infiltration, increased levels of MIP-2 and ASMase activity in plasma and slight
alterations in gas exchange.
Consequently, these data suggest that long exposure to low-stretch MV is directly
related with the development of inflammatory responses in animals previously
subjected to high-stretch mechanical ventilation or not. Furthermore, these results allow
us to conclude that adequate pulmonary surfactant functioning is essential for survival
of rats exposed to injurious and/or prolonged non-injurious mechanical ventilation and
its impairment does not precede the onset of acute lung injury in this model.
Chapter 3 174
General Discussion 175
General Discussion
General Discussion 176
General Discussion 177
The main objective of this thesis was to address the impact of mechanical
ventilation in the alveolar space and in particular the effects on the pulmonary surfactant
system. The thesis employed a translational animal model that permits investigation of
mechanical ventilation effects using different biochemical, biophysical, immunological,
cellular, and physiological techniques. As a result, we obtained significant data that
support the suggestion that proper functioning of pulmonary surfactant is essential for
the survival of animals exposed to high-stretch ventilation.
As is currently known, the development of ALI is due to multiple closely linked
factors, which hinders prognosis and diagnosis (173). This difficulty is transferred to
animal models where the variety of damage-inducing factors combines with the
assortment of animal and experimental designs to increase complexity (256, 350). Thus,
in 2010 an ATS Official Committee established the main features that characterize ALI
animal models (4). These features include histological evidence of tissue injury,
alteration of the alveolar-capillary barrier, presence of inflammatory responses, and
evidence of physiological dysfunction.
This thesis employed an animal model of VILI (10) due to its clinical relevance, as
MV is currently the only effective treatment for ALI (173). Accordingly, a model of
VILI using high tidal volumes (VT=25 ml/kg) and absence of positive end-expiratory
pressure application was established, as our aim was to provoke alveolar alterations.
Moreover, we also used a ventilator strategy characterized by the application of
moderated tidal volume and positive end-expiratory pressure (VT=9 ml/kg, PEEP=5 cm
H2O) because this is a conventional strategy widely applied in critical care units.
The first chapter of this thesis reported that our VILI model fulfilled all the
requirements established by the ATS Official Committee (4). In particular we observed
a significant decrease of arterial oxygen tension/inspiratory oxygen fraction ratio
(PaO2/FiO2< 300 mmHg), histological evidences of tissue injury, an increase of
inflammatory markers such as TNF- and acidic sphingomyelinase activity together
with increased levels of protein carbonyls in BAL and leakage of plasma proteins into
the alveoli. Besides, we also determined alterations in the composition and functionality
of pulmonary surfactant. In particular, we observed a marked decrease in levels of
surfactant apolipoproteins (SP-A, SP-B, and SP-C) and reduced expression of these
proteins by lung tissue. Furthermore, we observed that even though high-stretch
ventilation stimulated surfactant secretion by type II cells, surfactant was rapidly
General Discussion 178
inactivated. This inactivation can emerge due to presence of lipid peroxidation of
surfactant membranes, low content of surfactant apolipoproteins, and increased levels of
surfactant inhibitors such as C reactive protein (CRP) that insert into surfactant
membranes and critically affect surfactant physical properties (1).
Consequently, these results showed that injurious high-stretch ventilation produces
direct damage to the lung, promoting inflammation, oxidative stress, leakage of plasma
proteins into the alveolar space, and release of factors that altogether contributes to
inactivate lung surfactant.
However, during the previous study we realized that a small number of animals
subjected to high-stretch ventilation did not show evidence of physiological lung
dysfunction. Interestingly, prior to this study, Nin and co-workers also observed rats
resistant to injurious high-stretch ventilation (305). In light of all this information we
hypothesized that experimental animals facing the same stress may have heterogeneous
outcomes, as clinical patients have been observed to have different responses to the
same mechanical ventilation strategy (299, 349).
Hence, the aim of the next chapter was to identify factors involved in the resistance
outcome to ventilator-induced lung injury. To this end, we designed an experimental
model applying an endpoint criterion defined by the sacrifice of those animals with
mean arterial pressure values below 50 mmHg at 60 min, as these values are
incompatible with life in the short term. This criterion permitted us to establish two
different groups differentiated not only by hemodynamic and ventilatory values but also
by different alveolar alteration profiles.
As a result, in the second chapter, we observed that high-stretch ventilation
induced a susceptible and a resistant response. The susceptible response corresponded
to the damage profile observed in chapter 1. In particular, we observed that injurious
high-stretch ventilation induced exacerbated inflammatory response together with
alterations in the alveolar epithelial cells. On the other hand, even though the secretion
of pulmonary surfactant increased by high-stretch ventilation, the exacerbated
inflammatory response provokes surfactant inactivation, hindering the possibility of
fresh-active pulmonary surfactant replacement in the air-liquid interface. Consequently,
surface tension at the air-liquid interface increases, resulting in edema, hypoxemia, and
death.
General Discussion 179
On the other hand, the animals resistant to injurious high-stretch ventilation
increased the secretion of fresh pulmonary surfactant. However, pulmonary surfactant
from these resistant rats had normal protein and lipid composition, absence of lipid
peroxides and accomplished its biophysical, functions appropriately. As well, we
observed an attenuated proinflammatory response, indicated by increased levels of IL-6
but reduced levels of TNF-α, MCP-1, and MIP-2 and absence of acidic
sphingomyelinase activity in BAL. All together may contribute to the absence of edema
or gas exchange alterations. Therefore, these data suggest that injurious MV could
develop two different outcomes according to animal vulnerability. The key to their
survival resides in their weakened inflammatory response and the good functioning of
pulmonary surfactant, which seems to be a good damage maker as its impairment is
intimately related to worse outcomes.
Thus, these results suggest that there is a direct link between pronounced
proinflammatory response and surfactant inactivation in high-stretched rats. Also, they
reinforced our statement that correct functioning of pulmonary surfactant is essential for
survival in high-stretch ventilated rats.
This conclusion was further supported by the studies conducted in the third
chapter. Given the demonstration of heterogeneous outcomes, we speculated on
possible outcomes of the resistant group under low-stretch mechanical ventilation over
time. This study would attempt to simulate clinical situations in which stable patients
with pulmonary alterations would be subjected to conventional low-stretch mechanical
ventilation.
Unexpectedly, we observed that the maintenance of conventional low-stretch
mechanical ventilation worsened the animal's condition. In particular, we observed that
the animals ventilated under conventional low-stretch ventilation during prolonged
periods of time developed an inflammatory status characterized by neutrophils
infiltration and an increase in the concentration of pr-inflammatory cytokines in BAL
(IL-6 and MIP-2, but not TNF-α) and plasma (IL-6). However, the inflammatory status
was not damaging enough to alter the epithelial cells and the pulmonary surfactant
system.
In addition, we discovered that animals subjected to prolonged low-stretch
ventilation after exposition to high-stretch ventilation showed edema together with
neutrophils infiltration and slight alterations in gas exchange, whereas before the
General Discussion 180
application of prolonged low-stretch ventilation there was an attenuated inflammatory
status and absence of edema. Moreover, few animals did not survive the whole
ventilation process and were characterized by an exacerbated inflammatory response,
edema, alterations in pulmonary surfactant system and hypoxemia. These results were
consistent with the damage profile defined in the other chapters.
Therefore, the application of prolonged conventional low-stretch ventilation
triggers mechanotransduction processes that activate different pathways according to
the strategy applied and the vulnerability of the experimental animals to it. However,
only the vulnerable animals had altered pulmonary surfactant system and its function.
Consequently, these results suggested that the maintenance of conventional low-stretch
ventilation promotes alterations in the alveolar space, corroborated the existence of
different outcomes depending on vulnerability to mechanical ventilation, and
strengthened the hypothesis that proper functioning of pulmonary surfactant is essential
for survival in high-stretched rats. Furthermore, these results indicated that changes in
surfactant composition and function do not precede the onset of acute lung injury
induced by mechanical ventilation.
To conclude, the studies conducted in this thesis suggest that mechanical
ventilation developed two different outcomes according to animal vulnerability. This
vulnerability is mainly due to the outbreak of an exacerbated inflammatory response
that may promote alterations in the alveolar-capillary barrier and pulmonary surfactant.
Thus, we can conclude that impairment of pulmonary surfactant is an unequivocal VILI
characteristic tightly linked with the exacerbation of the inflammatory response.
181 Conclusions
Conclusions
182 Conclusions
183 Conclusions
The research presented in this thesis highlights alterations in the lungs after
exposition to mechanical ventilation. This research emphasizes the important role of
pulmonary surfactant. The results obtained using a translational animal model of
acute lung injury induced by mechanical ventilation allow us to conclude that:
Injurious high-stretch ventilation produces direct damage to the lung,
promoting pronounced inflammation, oxidative stress, leakage of plasma
proteins into the alveolar space, and release of factors that together contribute
to pulmonary surfactant impairment. Our results indicated that changes in lung
surfactant composition and function do not precede the onset of acute lung
injury induced by mechanical ventilation.
Experimental animals treated with the same mechanical ventilation strategy
have different outcomes according to their vulnerability to mechanical
ventilation, which are mainly differentiated by their inflammatory response.
VILI occurred in animal models only when surfactant was inactivated. There is
a direct link between pronounced proinflammatory response and surfactant
inactivation. In addition, we conclude that an attenuated inflammatory response
together with increasing endogenous, fully active surfactant pools protect
against the hypoxia and protein leakage that usually occur when ventilating
animals with injurious high-stretch ventilation.
With respect to the effect of non-injurious low-stretch ventilation, our results
indicate that inflammation in the lung was directly related to the duration of
conventional low-stretch ventilation and that proper functioning of pulmonary
surfactant is essential for survival of rats exposed to injurious and/or prolonged
non-injurious mechanical ventilation.
184 Conclusions
185 References
References
186 References
187 References
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